Analysis of y-chromosome str markers

ABSTRACT

The methods and compositions provided herein relate to the discovery of 13 STR markers, found on the human Y chromosome, having surprisingly high mutation rates when compared with 173 other Y-STR markers known today. The set of RM-Y-STRs may overcome the current dilemma of Y-chromosome analysis in forensic applications due to their extraordinary mutation properties. Embodiments of the invention include methods for allelic determination of rapidly-mutating Y-STR markers, amplification primers for the analysis of rapidly-mutating Y-STR markers, allelic ladders for analysis of rapidly-mutating Y-STR markers, and kits for the analysis of rapidly-mutating Y-STR markers.

This application claims priority to U.S. Provisional Application No. 61/241,778, filed Sep. 11, 2009, U.S. Provisional Application No. 61/367,346 filed Jul. 23, 2010, and to U.S. Provisional Application No. 61/379,340 filed Sep. 1, 2010. Application Nos., Ser. Nos. 61/241,778, 61/367,346 and 61/379,340 are incorporated by reference herein in their entirety for any purpose.

SEQUENCE LISTING

The instant application contains a Sequence Listing which has been submitted in ASCII format via EFS-Web and is hereby incorporated by reference in its entirety. Said ASCII copy, created on Apr. 29, 2011, is named LT00059.txt and is 748,407 bytes in size.

FIELD

Embodiments of the subject inventions are in the field of the forensic analysis of DNA.

BACKGROUND

The use of STR markers has become a standard tool in the analysis of DNA found at crime scenes. In most cases, the use of autosomal STR markers are used because, in part, of the high level of polymorphisms within most populations. For example, the 13 CODIS loci that are the standard for databasing criminal suspect in DNA in the United States are autosomal STR markers. In many cases with mixed stains from male and female contributors, particularly rape cases, forensic investigators must analyze genetic markers found on the Y chromosome to identify the male component usually belonging to the perpetrator of the crime. This is because in such cases, the autosomal STR markers are not informative due to profile overlap between e.g. female victim DNA and male perpetrator DNA. Although there are technical possibilities (i.e. differential lysis) to preferentially access male DNA, such techniques are often not successful. Because female DNA lacks a Y chromosome, the analysis of Y chromosomal markers can be used in samples that contained high levels of female DNA relative to the male DNA in the sample. Analyzing the Y chromosomal DNA hence excludes the complicating artifacts caused by the excess female source DNA.

The non-recombining nature allows the use of Y chromosome markers for male lineage identification, i.e. groups of males that are paternally related and hence share the same Y-STR haplotype i.e. based on currently-used Y-STR markers in forensics. Male lineage identification has become a valuable tool in forensic genetics to exclude males. However, in cases of non-exclusion (i.e. matching Y-STR profiles) no individual-based statement can be made based on the currently-available Y-STR markers because the same probability of having donated the crime scene sample applies to a male suspect and all his male relatives. This clearly is a limitation in forensic application where individual-based conclusions are anticipated. However, mutation events can occur at Y-STR markers. These mutations in the Y-STR marker can in principle enable the investigator to distinguish between closely related male relatives, and also between more distantly related males, provided such mutations occur in high-enough frequencies to be observable in a give pair of male relatives. Mutations in the currently available Y-STR markers are fairly infrequent events, occurring on the order of about 0.1 to 0.4% (1-4 changes per thousand generational events per each Y-STR locus). Thus even when relatively large numbers of Y-STR markers, i.e. those 17 markers applied to forensic applications today, are used the probability of distinguishing between male relatives is still remote. However, if enough Y-STRs markers that mutate more rapidly than the currently-known Y-STRs would be available, it can be expected that closely related males as well as distantly related males become differentiable based on Y-STR mutations towards male individual identification as anticipated in forensic applications.

The inventors have discovered a subset of thirteen Y-STR markers that have a significantly higher mutation rate than most Y-STR markers including those that are in general use. This finding is expected to revolutionize Y chromosomal applications in forensic biology, from previous male lineage differentiation methods. This finding also leads the way for male individual identification. Thus, by using one or more, by using two or more of such rapidly-mutating Y-STR markers (RM Y-STRs), the ability to distinguish between close and distantly related male relatives is significantly increased.

SUMMARY

Certain embodiments of the invention include methods of identifying an individual by determining the allele of at least 2 Y-STR markers selected from the group consisting of the rapidly-mutating Y-STR markers: DYF387S1, DYF399S1, DYF403S1, DYF404S1, DYS449, DYS518, DYS526, DYS547, DYS570, DYS576, DYS612, DYS626 and DYS627. In some embodiments of the subject methods, the alleles can be identified by PCR. In some embodiments of the subject methods, the alleles can be identified by mass spectroscopy. The PCR can be multiplexed PCR so as to co-amplify the at least 2 of the rapidly-mutating Y-STR markers. Certain embodiments of the invention include set of amplification primer pairs comprising primers for the amplification of at least 2 Y-STR markers selected from the group consisting of DYF387S1, DYF399S1, DYF403S1, DYF404S1, DYS449, DYS518, DYS526, DYS547, DYS570, DYS576, DYS612, DYS626 and DYS627. The primers set can co-amplify at least 2-13 of the rapidly-mutating Y-STR markers. In certain embodiments the primer set can co-amplify autosomal STR markers in addition to rapidly-mutating Y-STR markers. In some embodiments, the autosomal STRs can be selected from the group consisting of D3S1358, vWA, FGA, D8S1179, D21S11, D18S51, D5S818, D13S317, D7S820, D16S539, THO1, TPDX, and CSF1PO. In some embodiments the primers can be labeled with a fluorescent dye. Other embodiments provided are allelic ladder size standard for calling one or more alleles of an STR from at least 2 of the Y-STR markers selected from the group consisting of DYF387S1, DYF399S1, DYF403S1, DYF404S1, DYS449, DYS518, DYS526, DYS547, DYS570, DYS576, DYS612, DYS626 and DYS627. Other embodiments provided are kits for identifying the allele of at least 2 Y chromosome STRS markers, wherein the markers are selected from the group consisting of DYF387S1, DYF399S1, DYF403S1, DYF404S1, DYS449, DYS518, DYS526, DYS547, DYS570, DYS576, DYS612, DYS626 and DYS627, the kit comprising primers for the amplification of at least 2 rapidly-mutating Y-STR markers, and an allelic ladder representative of the selected markers.

BRIEF DESCRIPTION OF THE DRAWINGS AND TABLES

FIG. 1. Mutation rates of 186 Y-STR markers established from father-son pair analysis. Distribution of 186 Y-STR markers according to their Bayesian-based mutation rates (with credible intervals) estimated from analyzing up to 1966 DNA confirmed father-son pairs per each marker. The 13 rapidly-mutation (RM) Y-STR markers ascertained for further family/pedigree analysis are highlighted in red, and the commonly-used 17 Yfiler Y-STRs are in green. Multi-copy Y-STRs are noted with a black insert diamond.

FIG. 2. Correlation between the length of the longest homogeneous array, or the total number of repeats within a locus, and the allele-specific mutation rate from 267 Y-STR loci. Although the number of repeats present within a locus” longest homogenous array can be used to predict mutability, the total number of all repeats present within the locus has higher predictive value.

FIG. 3. Relationship between total number of repeats and mutation direction and rate from 267 Y-STR loci. Repeat loss mutations (contractions) displayed an exponential relationship with the total number of repeats, with increasing rates of loss rates at loci with higher numbers of repeats. Repeat gain mutations (expansions) showed a weak quadratic function, with a peak in gain rate at 20 total repeats.

FIG. 4. Male relative differentiation with newly-identified 13 RM Y-STRs and commonly-used 17 Yfiler Y-STRs. Results from differentiating between male relatives from analyzing 103 pairs from 80 male pedigrees, sorted according to the number of generations separating pedigree members, based on 13 RM Y-STRs and 17 Yfiler Y-STRs. Error bars represent 95% binomial confidence intervals. Note that these samples are independent from the father-son pairs initially used to establish the Y-STR mutation rates.

Table 1. Mutation rate estimations from the posterior distributions (medians and 95% credible intervals) of 186 Y-STR markers from analyzing up to 1966 DNA-confirmed father-son pairs. Markers with median mutation rates above 10⁻² (the RM Y-STR set) are highlighted. Additionally included are marker repeat structures (SEQ ID NOS 1-187, respectively, in order of appearance), number of gains/losses, total mutations and total number of father-son transmissions observed. PCR primers (Primer 1 sequences disclosed as SEQ ID NOS 188-357 and Primer 2 sequences disclosed as SEQ ID NOS 358-527, respectively, in order of appearance), PCR annealing temperature and locus assignment to the 54 multiplexes and three RM Y-STR multiplexes used for genotyping are included.

Table 2. Details of the 924 mutations observed among 120 Y-STR markers from screening a total of 352,999 meiotic transfers at 186 Y-STR markers. The repeat structure of both the father and son's alleles at the mutated Y-STR are given where possible (SEQ ID NOS 528-2196, respectively, in order of appearance). In the case of multi-copy markers with multiple variable segments within the amplicon, total repeat numbers or amplicon size is given in the absence of sequence information. The age of the father at the time of the son's birth is given, as is an individual pair reference.

Table 3. Comparison of 13 rapidly mutating RM Y-STRs and 17 Yfiler Y-STRs to differentiate between male relatives by one or more mutations from analyzing 103 pairs from 80 male pedigrees according to the number of generations separating members of the same pedigree.

DEFINITIONS

A “mutation” in a Y-STR marker is a change in the length of the repeat region of an STR marker or a change in the length (i.e., number) of the bases that are interspersed with the repeat units. For example, the addition of one more repeat unit is mutation resulting in the appearance of a new allele. In another example, the addition of a single base within a single repeat unit is also a mutation resulting in the appearance of a new allele. Such changes can result form the addition or deletion of one or more repeat units (or fractions thereof). Such sequence changes are readily detected by methods of analysis that are capable of detecting variations in nucleic acid sequence length or nucleic acid base order.

The term “rapidly-mutating Y-STR marker” (RM Y-STRs) as used herein refers to the following 11 Y-STR markers: DYF387S1, DYF399S1, DYF404S1, DYS449, DYS526, DYS547, DYS570, DYS576, DYS612, DYS626 and DYS627.

As used herein, the term “allelic ladder” refers to a standard size marker consisting of amplified alleles from a given STR locus or a size standards equivalent in size (or electrophoretic mobility) to the amplified alleles from a given STR locus. An allelic ladder can comprise a size standard for one or more alleles of a given STR marker. An allelic ladder can include alleles from different STR markers. The size standards in an allelic ladder can be labeled with a detectable label, e.g., a fluorescent dye.

The term “Y-STR marker” as used herein refers to an STR marker that is present on the non-recombining part of the human Y chromosome. Over 250 such Y-STR markers exist based on current knowledge. Y-STR markers are well-known to the person ordinary skill in the art. Database of Y-STR marker are publicly available, for example, at web sites, www.usystrdatabase.org and www.yhrd.org

The term “STR” as used herein refers to regions of genomic DNA which contain short, repetitive sequence elements. The sequence elements that are repeated are not limited to but are generally three to seven base pairs in length. Each sequence element is repeated at least once within an STR and is referred to herein as a “repeat unit.” The term STR also encompasses a region of genomic DNA wherein more than a single repeat unit is repeated in tandem or with intervening bases, provided that at least one of the sequences is repeated at least two times in tandem.

The term “Primer” as used herein refers to a single-stranded oligonucleotide or DNA fragment that hybridizes with a DNA strand of a locus in such a manner that the 3′ terminus of the primer can act as a site of polymerization and extension using a DNA polymerase enzyme. Primers can also DNA analogs in additions to or instead of naturally occurring DNA, e.g., LNAs, base analogs, and the like. “Primer pair” refers to two primers comprising a primer 1 that hybridizes to a single strand at one end of the DNA sequence to be amplified, and a primer 2 that hybridizes with the other end on the complementary strand of the DNA sequence to be amplified. “Primer site” refers to the area of the target DNA to which a primer hybridizes

As used herein, the terms “a,” “an,” and “the” and similar referents used herein are to be construed to cover both the singular and the plural unless their usage in context indicates otherwise. Accordingly, the use of the word “a” or “an” when used in conjunction with the term “comprising” in the claims or specification may mean “one,” but it is also consistent with the meaning of “one or more,” “at least one,” and “one or more than one.” It is further noted that the claims may be drafted to exclude any optional element. As such, this statement is intended to serve as antecedent basis for use of such exclusive terminology as “solely,” “only” and the like in connection with the recitation of claim elements, or use of a “negative” limitation.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as is commonly understood by one of ordinary skill in the art to which these inventions belong. All patents, patent applications, published applications, treatises and other publications referred to herein, both supra and infra, are incorporated by reference in their entirety. If a definition and/or description is set forth herein that is contrary to or otherwise inconsistent with any definition set forth in the patents, patent applications, published applications, and other publications that are herein incorporated by reference, the definition and/or description set forth herein prevails over the definition that is incorporated by reference. The citation of any publication is for its disclosure prior to the filing date and should not be construed as an admission that the present invention is not entitled to antedate such publication by virtue of prior invention.

DESCRIPTION OF CERTAIN SPECIFIC EMBODIMENTS

Applicants have identified mutation rates for numerous Y-STRs by examining three areas: i) the lack of knowledge on Y-STR mutability based on a reasonably large number of loci as required for evolutionary and genealogical applications, ii) the limited knowledge on the molecular basis of Y-STR mutability, and iii) the lack of Y-STRs for familial differentiation in forensic, genealogical, and particular population applications.

In ˜2000 DNA-confirmed father-son pairs. Table 1 presents the mutation rates and characteristics for 186 Y-STR markers. Included are mutation rate estimates, most determined for the first time. Also evaluated were the diversity and DNA sequence data generated for all loci to investigate the underlying causes of Y-STR mutability. The suitability of the identified most mutable Y-STRs for male relative differentiation and their implication for Y-chromosome applications in forensic science have been tested and resulted in the identification of 13 rapidly mutating Y-STR (RM-Y-STR) markers.

The 13 Y-STR markers were found to have a mutational rate that is substantially higher than the 173 other Y-STRs tested. These rapidly-mutating markers are DYF387S1, DYF399S1, DYF403S1, DYF404S1, DYS449, DYS518, DYS526, DYS547, DYS570, DYS576, DYS612, DYS626 and DYS627. The mutation rates for these 13 RM-Y-STRs are all well above 10⁻², whereas all other 173 Y-STRs (94% of the loci tested) have mutation rates well below 10⁻² (usually 10⁻³ and lower) (FIG. 1). In particular, the locus-specific mutation rates of the 13 RM Y-STRs range from 0.0116 to 0.0744. In comparison, the 17 Y-STRs included in the AmpF/STR® YFiler™ PCR Amplification kit (YFiler Kit, sold by Applied Biosystems/Life Technologies, Foster City, Calif. USA, namely DYS456, DYS389I, DYS390, DYS389II, DYS458, DYS19, DYS385 alb*, DYS393, DYS391, DYS439, DYS635, DYS392, Y GATA H4, DYS437, DYS438, DYS448) have locus-specific mutation rates ranging from 0.0002 to 0.0065 as established recently based on a large number of >135,000 meiotic transfers (Goedbloed et al. 2009). Hence, Applicants have surprisingly discovered that the 13 RM-Y-STRs mutate 60-11 time more rapidly than YFiler kit Y-STRs that are most commonly used in forensic applications today. The surprisingly high mutation rate in these RM-Y-STR markers permits the increased likelihood of distinguishing between male members of the same paternal genetic lineage. The likelihood of discrimination between members of the same male lineage is even greater when multiple rapidly-mutating Y-STR markers are employed. Various embodiments of the invention provided herein include methods, reagents, and kits for determining the specific allele of one or more, of two or more, of three or more, of four or more, of five or more, and so on, of the subject rapidly-mutating Y-STR markers in a given sample for analysis.

Provided herein are various methods for determining the specific allele of one or more of the rapidly-mutating Y-STR markers. The specific alleles of the rapidly-mutating Y-STR markers can be determined using essentially the same methods and technologies that are used for the determination of alleles other types of STR markers. Such methods and technologies can readily be adapted by the person skilled in the art so as to be suitable for use in the allele determination of the rapidly-mutating Y-STR markers. Examples of such technology include DNA sequencing and sequence specific amplification techniques such as PCR, used in conjunction with detection technologies such as electrophoresis, mass spectroscopy, and the like. In some embodiments, PCR amplification products may be detected by fluorescent dyes conjugated to the PCR amplification primers, for example as described in PCT patent application WO 2009/059049. PCR amplification products can also be detected by other techniques, including, but not limited to, the staining of amplification products, e.g. silver staining and the like.

The specific allele of a given rapidly-mutating Y-STR marker can also be determined by any of a variety of DNA sequencing techniques that are widely available, e.g., Sanger sequencing, pyrosequencing, Maxim and Gilbert sequencing, and the like. Numerous automated DNA sequencing techniques are commercially available, the applied Biosystems 3130, the applied Biosystems 3100, the Illumina Genome Analyzer, the Applied Biosystems SOLiD system, the Roche Genome Sequencer FIx system and the like.

DNA for analysis using the subject methods and compositions can be obtained from a variety of sources. DNA can be obtained at crime scenes, e.g., semen recovered from a rape victim. Additionally, DNA for analysis can be obtained directly from male subjects for the purpose of generating a database of allelic information (for subsequent analysis) or can be obtained from identified suspects.

DNA for analysis can be quantified prior to allelic analysis, thereby providing for more accurate allele calling. DNA quantity in a sample may be determined by many techniques known to the person skilled in the art, e.g., real time PCR. It is of interest to quantify the Y chromosomal DNA present in a sample for analysis prior to performing allelic analysis for Y-chromosomal STR markers, including rapidly-mutating Y-chromosomal STR markers. Autosomal DNA in the sample may also be quantitated, thereby providing a method for determining the background amount of female DNA present in a mixed sample, such as those samples recovered in rape cases.

A Y chromosomal haplotype can be established by determining the specific alleles present on a plurality of Y-STR markers. In general, the more rapidly a Y-STR marker mutates, the greater the probability of being able to distinguish between male relatives based on Y-chromosomal marker analysis. In some embodiments, the rapidly-mutating Y-STR markers can be analyzed by a method employing multiplex PCR. Multiplex PCR can amplify 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12 or all 13 of the rapidly-mutating Y-STR markers. In some embodiments, multiplex PCR can co-amplify additional Y-STR markers that are not part of the set of the subject rapidly-mutating Y-STR markers. In some embodiments, a multiplex PCR can provide for the co-amplification of one or more autosomal STR markers, e.g. the CODIS STR markers, D3S1358, vWA, FGA, D8S1179, D21S11, D18S51, D5S818, D13S317, D7S820, D16S539, THO1, TPDX, and CSF1PO. Detailed descriptions for the development of multiplex PCR for STR analysis can be found, among other places in PCT patent application WO 2009/059049 A1. In some embodiments the PCR reactions are not multiplexed. The amplicons that are produced in non-multiplex PCR reactions can be combined prior to the analysis of an instrument, e.g. a fluorescent DNA fragment analyzer (such as an automated DNA sequencer) or a mass spectrometer. Mass spectroscopy of STR markers is described in, among other places, U.S. Pat. No. 6,090,558.

Other embodiments include sets of PCR primers for the co-amplification of at least two rapidly-mutating Y-STR markers. Embodiments include sets of PCR primers for the co-amplification of 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12 or all 13 of the rapidly-mutating Y-STR markers provided herein. In some embodiments, PCR primer sets can comprise primers for the co-amplification of Y-STR markers that are not rapidly-mutating Y-STR markers. In some embodiments, the set of PCR primers can comprise PCR primers for the co-amplification of STR markers present on an autosome.

The embodiments of the invention also include allelic ladders to aid in the identification of alleles of rapidly-mutating Y-STR markers. The allelic ladders can comprise sets of size standards for 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12 or all 13 of the rapidly-mutating Y-STR markers. For each marker present in the allelic ladder, the allelic ladder can comprise standards for one or more alleles. An allelic ladder can comprise size standards for all known alleles of a given rapidly-mutating Y-STR marker, or any subset of known alleles. In some embodiments, the size standards in the allelic ladder can be labeled with one or more fluorescent dyes. In some embodiments an allelic ladder can further comprise size standards for autosomal STR markers. In some embodiments of allelic ladder can further comprise size standards for Y-STR markers that are not rapidly-mutating Y-STR markers.

Other embodiments of the subject invention include kits for the determination of the alleles for two or more rapidly-mutating Y-STR markers. Embodiments of the kits can comprise the subject sets of amplification primers. In some embodiments the kits can comprise one or more reagents used in nucleic amplification reactions. Examples of such reagents include, but are not limited to, DNA polymerases, dNTPs, buffers, nucleic acid purification reagents and the like. In some embodiments, the kits can comprise an allelic ladder designed to act as a size standard for the one or more rapidly-mutating Y-STR marker alleles generated (or potentially generated) by amplification primers present in the kit. Thus, in some embodiments, the kits can comprise allelic ladders specifically adapted to the amplicons generated by the use of the kit primers in an amplification reaction. For example a kit comprising primers for co-amplifying rapidly-mutating Y-STR markers DYF387S1, DYF399S1, and DYF404S1, can also include an allelic ladder having size standards for various alleles of rapidly-mutating Y-STR markers DYF387S1, DYF399S1, and DYF404S1. The kit can contain primers for co-amplifying all 13 RM-Y-STRs as well as an allelic ladder having appropriate size standards as would be known to one of skill in the art. The component size standards of an allelic ladder for given STR marker can be labeled with the same or different detectable labels, e.g., a fluorescent dye, as are the primers used to generate the amplicons of the actual allele in the sample for analysis.

The invention may be better understood by reference to the following examples comprising experimental data. Such information is offered to be examples and is not intended to limit the scope of the claimed invention. Examples and data presented herein were published in K. Ballantyne, et al. “Mutability of Y-Chromosomal Microsatellites: Rates, Characteristics, Molecular Bases and Forensic Implications” Am. J. Hum. Genet. 87:341-353 (Sep. 10, 2010), and published online Sep. 2, 2010, each incorporated by reference herein.

EXAMPLES DNA Samples

All father-son pairs used in the mutation rate study were confirmed in their paternity by molecular analyses, utilizing autosomal STRs, Y-STRs, HLA and RFLP genotyping and blood grouping, in addition to familial or governmental documentation. A threshold for paternity probability of 99.9% was set for inclusion in the study. Samples were obtained from the Berlin, Leipzig and Cologne areas of Germany, and the Warsaw and Wroclaw areas of Poland. Whole genome amplification using the GenomiPhi DNA Amplification kit (GE Healthcare, Little Chalfont, UK) was performed on the Leipzig samples due to low DNA quantities. WGA reactions were performed as recommended by the manufacturer, and products were purified using Invisorb 96 Filter Microplates (Invitek GmbH, Berlin, Germany). An additional set of independent samples from male relatives not used in the initial mutability screening from male families or pedigrees, used for verifying the value of identified rapidly mutating Y-STRs, came from the Greifswald, Kiel and Berlin areas of Germany, the Leuven area of Belgium, the Warsaw area of Poland, as well as Canada and Central Germany as described elsewhere 12. All families/pedigrees were confirmed by the same methods as the father-son pairs; pairs with complete genotypes for both the rapidly mutating (RM) Y-STRs and Yfiler Y-STRs were considered for analysis, or in the case of partial genotypes only those that showed a mutation at one or more loci were included. The use of all samples for the purpose of this study was in agreement with the institutional regulations and under informed consent.

Y-STR Markers and Genotyping Protocols

Y-STR markers were mostly selected from a previous study detailing a large number of 167 previously unknown Y-STRs 29, with the additional inclusion of Y-STRs known at the time of project commencement 42. The focus was on single-copy Y-STR markers in order to be able to fully confirm genotype differences by DNA sequence analysis when identifying mutations. However, given our aim to find RM Y-STRs, we included some additional multi-copy Y-STRs, especially those with high diversities (for which mutation confirmation was performed by independent genotyping). A complete list of loci, primer sequences and protocols can be found in the Supplemental Data S1. Seventeen of the 186 Y-STRs were genotyped with a commercially available kit, the AmpF/STR Yfiler PCR Amplification kit (Applied Biosystems), following the manufacturer's instructions. Full descriptions of protocols and markers can be found in (28). The remaining 169 Y-STRs were genotyped using 54 multiplex assays including 1 to 5 markers each. PCRs were performed using three differing protocols, and details are provided in the Supplemental Data S1. In addition, 13 Y-STRs identified during the study as rapidly mutating (RM) Y-STRs were genotyped using three multiplex assays in an independent sample set of male relatives. All PCRs were performed on GeneAmp PCR System 9700 machines (Applied Biosystems) at the Department of Forensic Molecular Biology, Erasmus MC Rotterdam. Fragment length analysis was performed using the 3130x/Genetic Analyzer (Applied Biosystems) at Applied Biosystems, Foster City, USA. Profiles generated were genotyped using GeneMapper software (ID v 3.2, Applied Biosystems). Genotype differences were identified using in-house developed Microsoft Excel 2007 macros. All mutations were confirmed by DNA sequence analysis in Rotterdam of both the father and son at the Y-STR locus, as described in M. Goedbloed, et al. (2009) Int. J. Legal. Med. 123, 471-482. Multi-copy Y-STR loci with three or more alleles were not able to be sequenced, but mutations were confirmed by at least two independent fragment length analysis amplifications.

Statistical Data Analyses

Mutation rates for individual markers were estimated using a binomial hierarchical Bayesian model 43 using the Marcov Chain Monte Carlo (MCMC) Gibbs sampling as implemented in WinBUGS, as described in Goedbloed. In brief, it was assumed that each mutation rate could be considered as a realization of the mutation rate underlying any Y-STR. In brief, we assumed that the mutation rate θi of Y-STR i was a sample from a common population distribution defined by hyperparameters φ. In that way, the estimated mutation rate of a Y-STR incorporates the information provided by the observed data on that Y-STR (number of observed mutations over all the observed father-son pair) and the information of the mutation rate of the Y-STR″ as estimated in the hyperparameter from all the Y-STRs. In practice, this implies that Y-STRs for which no mutation was observed are going to show a mutation rate (estimated from the posterior distribution) which is smaller than other Y-STRs where a large number of mutations are observed, but is always different from 0.

The mutation rate of each Y-STR was coded in a logit form, and assumed to follow a normal distribution with parameters μ and σ=1/σ to be estimated, as well as the particular mutation rates of each STR. As only very limited data was available prior to our study for the range of Y-STR mutation rates, we assumed diffuse, non-informative prior distributions for the hyperparameters. A non-informative prior normal distribution (μ=0, τ=1×10⁻⁶) was specified for the hyperparameter μ and a prior diffuse gamma distribution with parameters α=1×10⁻⁵ and β=1×10⁻⁵ for the parameter τ. Three MCMC chains using the Gibbs sampler were generated in parallel when estimating the mutation rate for each locus, with 100,000 runs performed for each chain. Mean, median and 95% credible intervals (CI) were estimated from the three chains after discarding the first 50,000 runs and performing a thinning of 15 in order to reduce the amount of autocorrelation between adjacent simulations. Locus-specific differences in mutation rates between the sampling populations (Cologne, Berlin, Leipzig, Warsaw and Wroclaw) were tested by means of a permutation analysis. The average mutation rate for each locus and each population was compared to a hypothetical permutated population, where each father-son pair had been assigned to a population at random, maintaining the original sample sizes for each locus. The number of times the permutated averaged mutation rate was larger than the observed rate was recorded, and used to obtain the one tail p value over 100,000 iterations. The lack of significant differences between populations allowed pooling of mutation rates across populations.

In order to investigate the mutation rate of the Yfiler and RM Y-STR sets rather than of each marker within the set, the total number of mutations observed between each father-son pair for each set was computed, given the number of Y-STRs analyzed. This parameter was then modeled under the Bayesian paradigm with a Poisson distribution. A prior with a Gamma distribution was used with a diffuse shape of 1 and a scale of 200, implying a mutation rate with a mean of 0.005 and a variance of 40000. The posterior distribution followed a conjugate Gamma distribution with shape of 1+(total number of mutations) and scale of 1/(1/(200+total number of markers used)). In order to estimate the probability of observing at least one mutation in each set, 100000 Monte Carlo replicates were performed with the rgamma function of the R package 45 from the estimated shape and scale of the posterior distribution of each set of Y-STRs.

For the RM Y-STR set a median mutation rate of 0.0197 (95% credible interval 0.018-0.022) was estimated that is about 7-fold higher as revealed for the YFiler set consisting of 17 markers with a median rate of 0.0028 (95% credible interval ranging from 0.0023 to 0.0035). Next, the probability of observing at least one mutation per Y-STR set in a given father-son pair, reflecting the minimal criteria for differentiating male relatives, was estimated as 1 minus the probability of observing 0 mutations, which is directly estimated from a Poisson distribution: The probability of observing at least one mutation (k) within either of the YSTR sets in any given father-son pair was directly estimated from the Poisson distribution:

P(k>0)=1−P(k=0)=1−e ^(−Nm),

with N representing the number of markers and m representing the average mutation rate of the set of markers obtained from the sampling from the posterior distribution. Assuming that all Y-STRs per set have been genotyped successfully, and using the posterior estimates of the mutation rate for each set of markers, the probability of observing at least one mutation with the RM Y-STR set is 0.1952 (95% credible interval of 0.177 to 0.21). This value is more than four times higher than that estimated for the YFiler set with 0.047 (95% credible interval of 0.038 to 0.057), although six more markers are included in the YFiler set relative to the RM Y-STR set. The molecular factors determining mutation rates were modeled using a Poisson regression with in-house developed Matlab scripts (v7.6.0.324, The Mathworks, Inc., Natick, Mass., USA). The mutation rate was modeled as a function dependent on of the repeat length, the sequence motif, the complexity of the locus and the length of the repeat in base pairs (tri-, tetra-, penta- or hexanucleotide), as:

$\mspace{79mu} {{p\left( y \middle| \theta \right)} = {{\prod\limits_{i = 1}^{n}{\frac{1}{y_{i}\text{?}}\left( {x_{i}\theta} \right)\text{?}}} - {\text{?}\text{?}}}}$ ?indicates text missing or illegible when filed

where θ is assumed to be dependent on the factors described above, in the form

θ=e ^(αL+βS+γC+δV+εR+ζN)

where L represents the length of the allele (number or repeats, either of the longest homogenous array or the total locus), S represents the sequence motif (comprised of the number of A, T, C or G nucleotides in the repeated sequence motif), C represents the complexity of the locus, either in binary or quantitative form, V is the number of variable motifs present, R is the repeat length, and N is the copy number of the locus. A stepwise regression procedure was used, with probability to enter ≦3.05, probability to remove ≧0.10. For clarity, the methods used for defining and calculating the number of repeats within a locus, and the complexity of that locus, are elucidated below.

Locus designations were modeled after Kayser et al., where at least 3 consecutive repeats of the same motif are required to define a given repeat segment as a locus, and any interruption of more than 1 base, but less than a full unit, is classed as ending the locus. Individual Y-STR loci contained between 1 and 5 repeat blocks, as in, for example, DYS612 with 5 blocks (CCT)5(CTT)1(TCT)4(CCT)1(TCT)19 (SEQ ID NO: 2197). If a locus contained more than one variable segment, and repeat numbers could not be assigned to all individuals at all repeat segments accurately, the locus was removed from the regression analysis. A segment was defined as variable if a variation in repeat number was seen in any individual sequenced, relative to the remainder of the population.

Number of repeats: The number of repeats in the longest homogenous array was directly counted, and the population average calculated for each locus. In addition, any additional repeats around the longest array were added to calculate the total number of repeats for each locus. In the above example for DYS612, the length of the longest array is 19, while the total number of repeats is 30.

Repeat Length: The length in base pairs of the repetitive motif, which ranged from 3 to 6 (included tri-, tetra-, penta-, hexa- and heptanucleotide repeats).

Complexity: Two complexity statistics were calculated per locus. First, a binary classification system was used, where loci with only one repetitive segment (e.g. (GATA)10 (SEQ ID NO: 2198)) were classified as simple, while any locus with two or more repetitive segments consisting of more than three consecutive repeats (e.g. (GATA)10(CATA)3 (SEQ ID NO: 2199)) was complex. Second, more quantitative information was provided by Kayser et al.'s complexity formula:

$C = {\frac{n^{2}}{\left( {n - 1} \right)^{2}}\left( {1 - {\sum\limits_{i = 1}^{m}\left( \frac{s_{i}}{n} \right)^{2}}} \right)\left( {1 - {\sum\limits_{i = 1}^{l}\left( \frac{b_{i}}{n} \right)^{2}}} \right)}$

where n is the total number of repeats in the locus, s, is the number of repeats of the ith sequence motif, and bi is the number of repeats in the ith block. Correlation and log linear regression analyses were carried out in SPSS v15.0 (SPSS Inc.), as were all mean comparison tests (utilizing ANOVA, Mann-Whitney U and Kruskal Wallis).

Repeat Length: The length in base pairs of the repetitive motif, which ranged from 3 to 6 (included tri-, tetra-, penta-, hexa- and heptanucleotide repeats).

Mutation Rates of Y-STR Markers

In order to define the expectation for a given RM Y-STR set to differentiate between male relatives, and to compare such potential with that of the commonly-used YFiler set, an average mutation rate for each of the two Y-STR sets applying a Bayesian approach was obtained. The number of mutations observed in one father-son pair for a set of STRs was modeled by means of a Poisson distribution. A prior conjugate Gamma distribution with a diffuse shape of 1 and a scale of 1/0.005 was used. The posterior distribution followed a Gamma distribution with shape of 1+total number of mutations and scale of 1/(1/0.005+total number of markers used) was obtained and 100000 Monte Carlo replicates were performed.

Furthermore, to test in independent samples whether the new RM Y-STR set is practical and useful for differentiating male relatives, genotyping was performed on both marker sets in 107 pairs from 80 male pedigrees who were related by between 1 and 20 generations within their pedigrees and compared the findings with those from YFiler also generated. Pedigrees came from the Greifswald and Kiel (N. von Wurmb-Schwark, V. Mályusz, E. Simeoni, E. Lignitz, M. Poetsch, For. Sci. Int 159, 92-97 (2006)), as well as Berlin (new to this study) areas of Germany, the Leuven area of Belgium (new to this study), the Warsaw area of Poland (new to this study), as well as from Canada C. Moreau, H. Vezina, V. Yotova, R. Hamon, P. de Kniff et al., Am. J. Phys. Anthropol. 139, 512-522 (2009), M. Vermeulen, A. Wollstein, K. van der Gaag, O. Lao, Y. Xue et al., For. Sci. Int. Genet., 3, 205-213 (2009) and Central Germany M. Kayser, M. Vermeulen, H. Knoblauch, H. Schuster, M. Krawczak, L. Roewer, For. Sci. Int. Genet. 1, 125-128 (2007)), as described elsewhere. All pedigrees were confirmed by DNA data (including autosomal STR, HLA and RFLP typing, Y-STR and Y-SNP typing, and mtDNA sequencing amongst various pedigrees), as well as additionally by familial or governmental documentation records. Only pairs which had complete genotypes for both sets, or in the case of partial genotypes, showed a mutation at one or more loci, were included in the calculations. Results are provided in FIG. 2. The RM Y-STR set distinguished over 65% of pairs by at least 1 mutation, reflecting a 5-fold increase in the level of male relative differentiation compared to the YFiler set with only 13%, similar to our statistical expectations from the initial father-son pair analyses. Within the pedigrees, the RM Y-STR set distinguished 60% of father-son pairs, 54% of brothers, and 87% of second cousins. If relatives were separated by more than 11 meioses, 100% of individuals were separated by 1 or more mutations using the RM Y-STR set. In contrast, the Y-filer set distinguished in this dataset no father son pairs, no second cousins, and only 6% of brothers in this dataset.

186 tri-, tetra- penta- and hexanucleotide Y-STR markers were screened for mutations in up to 1966 DNA-confirmed father-son pairs per marker by multiplex fluorescence-based fragment length analysis, giving direct observation of 352,999 meiotic transfers (for technical details see Table 1). To confirm mutations, all Y-STR genotype differences observed between fathers and their sons were confirmed by DNA sequence analysis for single copy and duplicated markers, or by duplicate fragment length genotyping analysis for multi-copy Y-STRs with more than 2 copies (where sequence analysis was not informative). Overall, we identified 924 confirmed mutations at 120 (64.5%) of the 186 Y-STR markers studied (details of each mutation observed can be found in Supplemental Data S2). For 66 Y-STR markers, the up to 1966 father-son pairs analyzed did not allow us to detect mutations due to a very low underlying mutation rate. The large number of Y-STR markers employed identified the range of Bayesian-based mutation rates estimated from the median of the posterior distribution to be between 3.81×10⁻⁴ (95% CI 1.38×10⁻⁶ to 2.02×10⁻³) and 7.73×10⁻² (6.51×10⁻² to 9.09×10⁻²) per marker, per generation (FIG. 1, Table 1). Ninety-one Y-STR markers (48.9%) had mutation rates in the order of 10⁻³, a further 82 markers (44%) in the order of 10⁻⁴, and 13 (6.9%) in the order of 10⁻². Across all 186 Y-STR markers, the average mutation rate was 3.35×10⁻³ (95% CI 1.79×10⁻³ to 6.38×10⁻³) with an average rate of 4.26×10⁻³ (95% CI 2.38×10⁻³ to 7.60×10⁻³) for the 122 tetranucleotide repeats as the largest repeat-length subgroup of Y-STR markers included here. Notably, the 13 Y-STR markers with mutation rates above 1×10⁻² representing only 7% of the markers studied, which we termed “Rapidly mutating Y-STRs” (RM Y-STRs), covered a large number of 462 of the 924 (50%) mutations observed in the study.

Number of Repeats.

Two estimates of the average number of repeats were calculated for each Y-STR locus i) the average repeat number in the longest homogenous array; and ii) the repeat number of the longest homogeneous array plus any non-variable repeats immediately adjacent (in accordance with previously defined rules for motif structure 29). Our regression analysis showed that while the number of repeats in the longest homogenous array did influence the mutation rate significantly, with higher numbers of repeats increasing the mutation rate (Wald χ²=2.41×10⁶, p<0.0001), including the number of non-variable repeats surrounding the array provided slightly more accurate information to the model (Wald χ²=3.03×10⁶, p<0.0001, FIG. 2). The effect size within the model was estimated with a partial η² of 0.798, indicating that the variance in the total number of repeats between loci accounts for ˜78% of the overall (effect+error) variation in Y-STR mutation rates observed. In addition, a statistically significant exponential relationship was observed between the total number of repeats and the allele-specific mutation rate (R²=0.707, p=6.84×10⁻⁹). In addition, there was a strong relationship between the total number of repeats and the direction of mutation (FIG. 3). Longer alleles displayed an exponential and statistically significant tendency towards repeat losses (contractions) (R²=0.585, p=8.27×10⁻⁷), while shorter alleles gained repeats (expansion) significantly more frequently (R²=0.238, p=0.011). The expansion mutation rate had a quadratic distribution, with a vertex around 19 repeats.

Male Relative Differentiation by RM Y-STRs

We identified 13 rapidly-mutating (RM) Y-STR markers (all with mutation rates >1×10⁻²); DYF387S1, DYF399S1, DYF403S1, DYF404S1, DYS449, DYS518, DYS526, DYS547, DYS570, DYS576, DYS612, DYS626 and DYS627 (FIG. 1, Table 1). Four of these 13 RM Y-STR markers are multi-copy systems (DYF387S1 with two, DYF399S1 with three, DYF403S1 with four, DYF404S1 with two and DYS526 with two copies), whereas nine were single-copy Y-STR markers (although six of these markers contained multiple Y-STR loci within the single amplicon, and only two, DYS570 and DYS576, were simple repeats with only one Y-STR locus respectively). The 13 RM Y-STRs were combined into a set under the hypothesis that closely related males (even father-son or brother pairs) may be differentiable by Y-STR mutations if RM Y-STRs are combined. In principle, one mutation at one of the 13 RM Y-STRs would be enough for individual differentiation.

In order to define a statistical expectation for the RM Y-STR set to differentiate between male relatives, and to compare their potential with that of the commonly used Yfiler set, we first computed the mutation rate observed for each of the two Y-STR sets by means of a Bayesian approach. The number of mutations observed in each father-son pair for each set of Y-STRs was modeled by means of a Poisson distribution. For the RM Y-STRs a median mutation rate of 1.97×10⁻² (95% CI 1.8×10⁻²-2.2×10⁻²) of the posterior distribution was estimated, which was 6.5-fold higher than that estimated for Yfiler Y-STRs with a median rate of 3.0×10⁻³ (95% CI ranging from 2.39×10⁻³ to 3.72×10⁻³). Next, the probability of observing at least one mutation in each of the two Y-STR sets for a given father-son pair was estimated, reflecting the minimal criteria for differentiating male relatives. Assuming that all Y-STRs per set were genotyped successfully, and using the posterior estimates of the mutation rate for each set of Y-STR markers, the probability of observing at least one mutation with the RM Y-STR set was 0.1952 (95% CI of 0.177 to 0.21). This value was surprisingly more than four times higher than that estimated for the Yfiler set with 0.047 (95% CI of 0.038 to 0.057). The probability of observing at least one mutation with the RM Y-STR set was statistically significantly higher than for the Yfiler set (p<5.0×10⁻⁰⁷). Finally, samples were empirically tested independent of those samples used for mutation rate establishment whether the new RM Y-STR set is practically useful for differentiating male relatives. For this, 103 male relative pairs from 80 male pedigrees who were related by between 1 and 20 generations within their pedigrees were genotyped and compared with the findings with those obtained from Yfiler kit in the same samples. Overall, the RM Y-STR set distinguished 70.9% pairs of male relatives by at least 1 mutation, reflecting a 5-fold increase in the level of male relative differentiation compared to the Yfiler kit set with only 13%; notably, the significant difference (t=6.389, p<0.0001) is similar to statistical expectations from the initial father-son pair analyses (FIG. 4 and Table 3). Within the pedigrees, the RM Y-STR set distinguished 70% of father-son pairs, 56% of brothers, and 67% of cousins (FIG. 4 and Table 3). In contrast, the Yfiler set was not able to differentiate any of the father-son pairs nor cousins, and only 6% of the brothers in this dataset (FIG. 4 and Table 3). Furthermore, all relatives separated by more than 11 generations were differentiable by 1 or more mutations using the RM Y-STR set, but only 33% with the Yfiler set.

All of the compositions and methods disclosed and claimed herein can be made and executed without undue experimentation in light of the present disclosure. While the compositions and methods of this invention may have been described in terms of specific examples or preferred embodiments, these examples and embodiments are in no way intended to limit the scope of the claims, and it will be apparent to those of skill in the art that variations may be applied to the compositions and/or methods and in the steps or in the sequence of steps of the methods described herein without departing from the concept, spirit and scope of the invention. More specifically, it will be apparent that certain agents which are both chemically and physiologically related may be substituted for the agents described herein while the same or similar results would be achieved. All such similar substitutes and modifications apparent to those skilled in the art are deemed to be within the spirit, scope and concept of the invention as defined by the appended claims.

TABLE 1 Bayesian median mutation rates, mutation summaries and repeat structures of 186 Y-STRs from analysing DNA-confirmed father-son pairs. Loci with median mutation rates above 10⁻² (the RM Y-STR set) are highlighted in red. Additionally included are PCR primers, PCR annealing temperature and locus assignment to the 54 multiplexes used for genotyping. Bayesian Bayesian median 95% Primer 1 Primer 2 Repeat Structure (as defined in Methods mutation credible Gains/ Total Total Sequence Sequence Ta in Multi- GBD ID and Materials) rate interval Losses Mutations Meioses 5′-3′ 5′-3′ ° C. plex Ref DYF380S1 (AAT) ₈₋₁₁ 3.84 × 10⁻⁴ 1.42 × 10⁻⁵-2.06 × 0/0 0 1790 AGCCATGTGGAT GACAAACCCATCC TD 28 [29] 10⁻³ TCACCACT TGTCTCC 70-50 DYF381S1 (TTG) ₇₋₈ 3.95 × 10⁻⁴ 1.43 × 10⁻⁵-2.07 × 0/0 0 1774 TCCATCCATCAA CAACCCAAACACT TD 45 [29] 10⁻³ TCCATCAA TGCAGAA 60-50 DYF381S2 (AAC) ₇₋₈ 3.91 × 10⁻⁴ 1.44 × 10⁻⁵-2.11 × 0/0 0 1756 CAACCCAAACA TCCATCCATCAAT TD 20 [29] 10⁻³ CTTGCAGAA CCATCAA 60-50 DYF382S1 (GGAT) ₉₋₁₆(AGAT)₁(GGAT)₃N₈(GGAC)₃ 1.05 × 10⁻³ 1.52 × 10⁻⁴-3.47 × 1/0 1 1609 TTGTAAAATGGG CCCAAAGTGCTAC TD 54 [29] 10⁻³ CATGTGGA CCACCTA 70-50 DYF386S1 (AAT) ₇₋₁₆ 6.02 × 10⁻³ 3.10 × 10⁻³-1.04 × 3/7 10 1772 GACTGCTCAACT CCAATGTTACTCA TD 29 [29] 10⁻² GCACTCCA CTATGCTGCTT 70-50 DYF387S1 (AAAG)₃(GTAG)₁(GAAG)₄N₁₆(GAAG)₉ 1.59 × 10⁻² 1.08 × 10⁻²-2.24 × 15/13 28 1804 GCCTGGGTGAC GCCACAGTGTGAG TD 49 [29] (AAAG) ₁₃ 10⁻² AGAGCTAGA AAGTGTGA 70-50 DYF388S1 (CTTC)₆ (CTTT) ₅₋₁₉N₁₈(CTTC)₃(TTTC)₁ 6.85 × 10⁻³ 3.64 × 10⁻³-1.15 × 5/6 11 1702 TTCTAGGAAGAT CCCAGACAACAG TD 52 [29] (CTTC)₃N₈(CTTC)₃N₃₂(CTTC)₃ 10⁻² TAGCCACAACA AGCAAAAC 65-50 DYF390S1 (TTTA) ₉₋₁₄ 9.95 × 10⁻⁴ 1.42 × 10⁻⁴-3.34 × 0/1 1 1680 AGCATTCCCTTT TGACGAGTTAGTG TD 12 [29] 10⁻³ CTCATTGC GGTGCAG 70-50 DYF393S1 (AAG)₄(AA)₁ (AAG) ₁₆₋₃₀(CAG)₁₋₂ 8.57 × 10⁻³ 4.91 × 10⁻³-1.37 × 9/5 14 1712 GCAACCAAAAG GTGGAGCCTGCTT TD 31 [29] 10⁻² GTTTGGAGA AAAGGAA 70-50 DYF394S1 (ATT)₃(GTT)₁ (ATT) ₆₋₉ 3.91 × 10⁻⁴ 1.40 × 10⁻⁵-2.09 × 0/0 0 1768 GCCCTGAACAA GCAGTGAGCTGAG TD 24 [29] 10⁻³ AATCTGGAG ATGGTGA 70-50 DYF396S1 (TCT) ₆₋₉ 3.86 × 10⁻⁴ 1.37 × 10⁻⁵-2.06 × 0/0 0 1785 TGCACGTCTTCA TTGAATGCCAAGT TD 36 [29] 10⁻³ TACATAGAGC TATGTAGCA 70-50 DYF399S1 (GAAA)₃N₇₋₈ (GAAA) ₁₀₋₂₃ 7.73 × 10⁻² 6.51 × 10⁻²-9.09 × 55/84 139 1794 GGGTTTTCACCA CCATGTTTTGGGA TD 49 [29] 10⁻² GTTTGCAT CATTCCT 70-50 DYF401S1 (AAGG)₃(AAGC)₁(AAGG)₃N₃₉(AAGG)₃ 6.50 × 10⁻³ 3.08 × 10⁻³-1.18 × 3/5 8 1333 TCGCAAACATA TTCTAGGAAGATT TD 48 [29] N₈(AAGG)₃(AAAG)₁(AAGG)₃N₁₃ 10⁻² GCACTTCAG AGCCACAACA 70-50 (AAAG) ₈₋₂₃G(AAGG)₆ DYF403S1a (TTCT) ₁₀₋₁₇ N ₂₋₃ (TTCT) ₃₋₁₇ 3.10 × 10⁻² 2.30 × 10⁻²-4.07 × 29/17 46 1504 CAAAATTCATGT ACAGAGCAGGATT TD 54 [29] 10⁻² GGATAATGAG CCATCTA 70-50 DYF403S1b (TTCT)₁₂N₂ (TTCT) ₈ (TTCC) ₉ (TTCT) ₁₄ 1.19 × 10⁻² 7.05 × 10⁻³-1.86 ×  5/11 16 1402 CAAAATTCATGT ACAGAGCAGGATT TD 54 [29] N₂(TTCT)₃ 10⁻² GGATAATGAG CCATCTA 70-50 DYF404S1 (TTTC) ₁₀₋₂₀N₄₂(TTTC)₃ 1.25 × 10⁻² 7.92 × 10⁻³-1.84 × 14/7  21 1739 GGCTTAAGAAA CCATGATGGAACA TD 38 [29] 10⁻² TTTCAACGCATA ATTGCAG 70-50 DYF405S1 (GGAA) ₄₋₁₄N₁₁₅(GGAA)₃ 1.52 × 10⁻³ 3.54 × 10⁻⁴-4.13 × 1/1 2 1756 CCGTGGTGTCTG CACATCAAGTTGC TD 26 [29] (GAAA)₁(GGAA)₃ 10⁻³ AAGCATAG CTGTTTCA 70-50 DYF406S1 (TATC) ₈₋₁₄ 3.82 × 10⁻³ 1.61 × 10⁻³-7.48 × 3/3 6 1744 CCTGGGTGACA TCCACCAAAATTC TD 28 [29] 10⁻³ CAGTGAGACT CATGACA 70-50 DYF410S1 (AAAT) ₇₋₁₃ 2.04 × 10⁻³ 4.82 × 10⁻⁴-5.52 × 2/0 2 1309 TGACGAGTTAGT GCGGCTAGGGTAG TD 48 [29] 10⁻³ GGGTGCAG AATCCAT 70-50 DYS19/ (TAGA)₃(TAGG)₁ (TAGA) ₆₋₁₆ 4.37 × 10⁻³ 1.98 × 10⁻³-8.23 × 4/3 7 1756 Yfiler Yfiler Yfiler Yfiler [29] DYS394 10⁻³ DYS385a (AAGG)₄N₁₄(AAAG)₃N₁₂(AAAG)₃N₂₉ 2.08 × 10⁻³ 6.24 × 10⁻⁴-5.06 × 2/1 3 1762 Yfiler Yfiler Yfiler Yfiler [29] (AAGG) ₆-₇ (GAAA) ₇₋₂₃ 10⁻³ DYS385b (AAGG)₄N₁₄(AAAG)₃N₁₂(AAAG)₃N₂₉ 4.14 × 10⁻³ 1.75 × 10⁻³-8.09 × 6/0 6 1615 Yfiler Yfiler Yfiler Yfiler [29] (AAGG) ₆₋₇ (GAAA) ₇₋₂₃ 10⁻³ DYS388 (ATT) ₉₋₁₈ 4.25 × 10⁻⁴ 1.51 × 10⁻⁵-2.26 × 0/0 0 1635 GTGAGTTAGCCG CAGATCGCAACCA TD 50 [29] 10⁻³ TTTAGCGA CTGCG 60-50 DYS389I (TCTG)₃ (TCTA) ₆₋₁₄ 5.51 × 10⁻³ 2.72 × 10⁻³-9.74 × 4/5 9 1751 Yfiler Yfiler Yfiler Yfiler [29] 10⁻³ DYS389II (TCTG) ₄₋₅ (TCTA) ₁₀₋₁₄N₂₈(TCTG)₃ 3.83 × 10⁻³ 1.61 × 10⁻³-7.49 × 2/4 6 1743 Yfiler Yfiler Yfiler Yfiler [29] (TCTA) ₆₋₁₄ 10⁻³ DYS390 (TCTG)₈ (TCTA) ₉₋₁₄(TCTG)₁(TCTG)₄ 1.52 × 10⁻³ 3.52 × 10⁻⁴-4.09 × 0/2 2 1758 Yfiler Yfiler Yfiler Yfiler [29] 10⁻³ DYS391 (TCTG)₃ (TCTA) ₆₋₁₅ 3.23 × 10⁻³ 1.26 × 10⁻³-6.65 × 3/2 5 1759 Yfiler Yfiler Yfiler Yfiler [29] 10⁻³ DYS392 (TAT) ₄₋₂₀ 9.70 × 10⁻⁴ 1.43 × 10⁻⁴-3.23 × 1/0 1 1728 Yfiler Yfiler Yfiler Yfiler [29] 10⁻³ DYS393/ (AGAT) ₇₋₁₈ 2.11 × 10⁻³ 6.21 × 10⁻⁴-5.00 × 2/1 3 1750 Yfiler Yfiler Yfiler Yfiler [29] DYS395 10⁻³ DYS425/ (TGT) ₈₋₁₄ 1.51 × 10⁻³ 3.48 × 10⁻⁴-4.08 × 1/1 2 1778 TGGAGAGAAGA AGTAATTCTGGAG TD 20 [29] DYF371 10⁻³ AGAGAGAAAT GTAAAATGG 60-50 DYS426 (GTT) ₉₋₁₂ 3.98 × 10⁻⁴ 1.49 × 10⁻⁵-2.11 × 0/0 0 1735 CTCAAAGTATGA GGTGACAAGACG TD 38 [29] 10⁻³ AAGCATGACCA AGACTTTGTG 70-50 DYS434 (ATCT) ₉₋₁₂ 4.04 × 10⁻⁴ 1.47 × 10⁻⁵-2.14 × 0/0 0 1715 CACTCCCTGAGT GGAGATGAATGA TD 40 [29] 10⁻³ GCTGGATT ATGGATGGA 60-50 DYS435 (TGGA) ₁₀₋₁₂ 1.00 × 10⁻³ 1.47 × 10⁻⁴-3.33 × 0/1 1 1676 AGCATCTCCACA TTCTCTCTCCCCCT TD 41 [29] 10⁻³ CAGCACAC CCTCTC 60-50 DYS436 (GTT) ₁₁₋₁₃ 3.84 × 10⁻⁴ 1.38 × 10⁻⁵-2.05 × 0/0 0 1798 CCAGGAGAGCA GCAATCCAACTTC TD 18 [29] 10⁻³ CACACAAAA AGCCAAT 60-50 DYS437 (TCTA) ₄₋₁₂(TCTG)₂(TCTA)₄ 1.53 × 10⁻³ 3.54 × 10⁻⁴-4.10 × 2/0 2 1760 Yfiler Yfiler Yfiler Yfiler [29] 10⁻³ DYS438 (TTTTC) ₇₋₁₆ 9.56 × 10⁻⁴ 1.37 × 10⁻⁴-3.18 × 0/1 1 1751 Yfiler Yfiler Yfiler Yfiler [29] 10⁻³ DYS439 (GATA)₃N₃₂ (GATA) ₅₋₁₉ 3.84 × 10⁻³ 1.63 × 10⁻³-7.54 × 2/4 6 1736 Yfiler Yfiler Yfiler Yfiler [29] 10⁻³ DYS441 (TTCC) _(12-21.2) 1.18 × 10⁻³ 1.66 × 10⁻⁴-3.93 × 1/0 1 1419 ATGTACCTGTAG AAGTTGCAGTGAG TD 27 [45] 10⁻³ CCCCAGTGAAC CGAAGATTG 70-50 DYS442 (GATA) ₉₋₁₆(GACA)₃ 9.78 × 10⁻³ 5.59 × 10⁻³-1.57 ×  2/12 14 1497 AAACGCCCATC CCCCAAGTCCCCA TD 16 [45] 10⁻² AATCAATGAGTG AAGTGTGT 70-50 DYS443 (TTCC) ₁₁₋₁₇(CTT)₃ 2.10 × 10⁻³ 6.24 × 10⁻⁴-5.01 × 2/1 3 1745 GAGTTCATGCTG TCATTGGCCACCT TD 29 [29] 10⁻³ ATGACAAGC GACATTA 70-50 DYS444 (TAGA) ₉₋₁₆ 5.45 × 10⁻³ 2.68 × 10⁻³-9.65 × 3/6 9 1775 TGTGAACCATTT TCACGTTGTTCAA TD 45 [29] 10⁻³ GGCATGTT GGGTCAA 60-50 DYS445 (TTTA) ₆₋₁₄ 2.16 × 10⁻³ 6.38 × 10⁻⁴-5.15 × 2/1 3 1704 GAGCTGAGATT AGTTAAGAGCCCC TD 32 [45] 10⁻³ ATGCCACCAAAA ACCTTCCTG 70-50 DYS446 (TCTCT) ₈₋₂₁ 2.67 × 10⁻³ 9.38 × 10⁻⁴-5.87 × 2/2 4 1747 TATTTTCAGTCT AAATGTATGGCCA TD 30 [45] 10⁻³ TGTCCTGTC ACATAGCAAAACC 70-50 DYS447 (TTATA) ₆₋₇(TTATT)₁ (TTATA) ₈₋₁₃ 2.12 × 10⁻³ 6.28 × 10⁻⁴-5.11 × 1/2 3 1722 GGGCTTGCTTTG GGTCACAGCATGG TD 27 [45] (TTATT)₁ (TTATA) ₅₋₉ 10⁻³ CGTTATCT CTTGGTT 70-50 DYS448 (AGAGAT) ₁₁₋₁₃N₄₂ (AGAGAT) ₈₋₉ 3.94 × 10⁻⁴ 1.41 × 10⁻⁵-2.11 × 0/0 0 1747 Yfiler Yfiler Yfiler Yfiler [45] 10⁻³ DYS449 (TTCT) ₁₃₋₁₉N₂₂(TTCT)₃N₁₂ (TTCT) ₁₃₋₁₉ 1.22 × 10⁻² 7.54 × 10⁻³-1.85 × 14/5  19 1617 TGGAGTCTCTCA CCATTGCACTCTA TD 46 [29] 10⁻² AGCCTGTTC GGTTGGAC 60-50 DYS450 (TTTTA) ₇₋₁₁N₁₂(TTTTA)₃ 1.04 × 10⁻³ 1.54 × 10⁻⁴-3.50 × 0/1 1 1598 GCCTTTCCAATT TGGAATATGATGC TD 39 [45] 10⁻³ TCAATTTCTGA AGCTGTTTGT 70-50 DYS452 (TATAC) ₅₋₁₄ [(CATAC) ₁ (TATAC) ₁]₂₋₄ 4.02 × 10⁻³ 1.56 × 10⁻³-8.28 × 2/3 5 1411 TTTATTATACTC GTGGTGTTCTGAT TD 16 [45] N₂₀(TATAC)₃(CATAC)₁(TATAC)₃ 10⁻³ AGCTAATTAATT GAGGATAAT 70-50 GGTT DYS453 (AAAT) ₉₋₁₅ 3.89 × 10⁻⁴ 1.43 × 10⁻⁵-2.08 × 0/0 0 1782 GGGTAACAGAA CTAAAAGTATGGA TD 45 [45] 10⁻³ CAAGACAGT TATTCTTCG 60-50 DYS454 (AAAT) ₇₋₁₃ 4.75 × 10⁻⁴ 1.71 × 10⁻⁵-2.55 × 0/0 0 1458 TCACAATGACCC GTTCTTTGGCCCT TD 46 [29] 10⁻³ TTTTGTGC GCATTTA 60-50 DYS455 (ATTT) _(6.2-11) 4.26 × 10⁻⁴ 1.59 × 10⁻⁵-2.28 × 0/0 0 1618 ATCTGAGCCGA GGGGTGGAAACG TD 39 [45] 10⁻³ GAGAATGATA AGTGTT 70-50 DYS456 (AGAT) ₁₁₋₂₃ 4.94 × 10⁻³ 2.35 × 10⁻³-8.97 × 6/2 8 1757 Yfiler Yfiler Yfiler Yfiler [45] 10⁻³ DYS458 (GAAA) ₁₁₋₂₄ 8.36 × 10⁻³ 4.80 × 10⁻³-1.34 × 7/7 14 1756 Yfiler Yfiler Yfiler Yfiler [45] 10⁻² DYS459 (ATTT) ₆₋₁₁ 2.67 × 10⁻³ 9.36 × 10⁻⁴-5.86 × 2/2 4 1741 CAGGTGAACTG TTGAGCAACAGAG TD 27 [45] 10⁻³ GGGTAAATAAT CAAGACTTA 70-50 DYS460 (TAGA) ₈₋₁₃ 6.22 × 10⁻³ 3.19 × 10⁻³-1.07 × 2/8 10 1717 GCCAAACTCTTT TCTATCCTCTGCC TD 20 [29] 10⁻² CCAAGAAG TATCATTTATTA 60-50 DYS461 (TAGA) ₈₋₁₃ 9.89 × 10⁻⁴ 1.40 × 10⁻⁴-3.29 × 0/1 1 1695 AGGCAGAGGAT TTCAGGTAAATCT TD 19 [29] 10⁻³ AGATGATATGG GTCCAGTAGTGA 60-50 AT DYS462 (CATA) ₉₋₁₄ 2.65 × 10⁻³ 9.20 × 10⁻⁴-5.80 × 1/3 4 1771 TGTGCTGTACCA CCAGCCTGAGCAA TD 30 [45] 10⁻³ GTTGCCTA GAGAGTA 70-50 DYS463 (AAAGG) ₆₋₇ (AAGGG) ₉₋₁₉ 1.51 × 10⁻³ 3.49 × 10⁻⁴-4.07 × 2/0 2 1776 AATTCTAGGTTT ATGAGGTTGTGTG TD 33 [45] 10⁻³ GAGCAAAGACA ACTTGACTG 70-50 DYS464 (CCTT) ₉₋₂₀N₄₆(CCTT)₃N₈(CCTT)₄ 7.27 × 10⁻³ 3.96 × 10⁻³-1.20 × 5/7 12 1745 TTACGAGCTTTG CCTGGGTAACAGA TD 31 [45] 10⁻² GGCTATG GAGACTCTT 70-50 DYS468 (CTG)₄N₄₄(CCT)₃N₄₀(CTT)₃N₃₅(CCT)₄N₈ 1.74 × 10⁻³ 4.03 × 10⁻⁴-4.69 × 1/1 2 1535 GGGAGTTCCAA GGGGGAAGATGA TD 37 [29] (CTC)₄ (CTT) ₇₋₉ (ATTCAT) ₈₋₁₀ 10⁻³ ACTTTTTCACA CAATGATG 70-50 DYS469 (CTT)₃N₃₉(CTT)₄(GTT)₁ (CTT) ₁₀₋₃₀T 2.99 × 10⁻³ 1.04 × 10⁻³-6.54 × 3/1 4 1555 TTTGGGGACTGA CCCCAGCTGGTAA TD 41 [29] (CTT)₃N₁₇(CTT)₅N₃₇(CTT)₃N₁₂(CTT)₄ 10⁻³ ATTCAAAA AATGAGT 60-50 N₁₂(CTT)₃N₁₂(CTT)₅(CCT)₄N₉(CTT)₃ (CCT)₃ DYS470 (GTT) ₈₋₁₂N₃₃(GTT)₃ 4.20 × 10⁻⁴ 1.51 × 10⁻⁵-2.23 × 0/0 0 1651 GGTCCTTCAGGA TGGCTGTAAAACA TD 44 [29] 10⁻³ ACCAGTTG AATATCAGCA 60-50 DYS472 (AAT) ₇₋₉ 4.46 × 10⁻⁴ 1.62 × 10⁻⁵-2.37 × 0/0 0 1549 AGATTGTCCCAC GAGGCACTGTGTT TD 1 [29] 10⁻³ CTGCACTC CAGCAAA 70-50 DYS473 (AAT)₈N₁₂ (AAT) ₉₋₁₃ 4.13 × 10⁻⁴ 1.47 × 10⁻⁵-2.21 × 0/0 0 1676 CAGCCTGGATA CCTCTTTTCTTTGC TD 44 [29] 10⁻³ GCAGAGTGA TGGTTCCTT 60-50 DYS474 (AAC) ₉₋₁₀ 3.92 × 10⁻⁴ 1.41 × 10⁻⁵-2.08 × 0/0 0 1766 CCCCTGAACTTA GGCATCTAGGTTT TD 22 [29] 10⁻³ AAAGGTGGA ACTGTGAGGA 60-50 DYS475 (TAA) ₇₋₉(CAA)₁(TAA)₃ 4.14 × 10⁻⁴ 1.54 × 10⁻⁵-2.21 × 0/0 0 1681 CCCACCAAGGG CCCACAGAAAGAT TD 23 [29] 10⁻³ TTTTCAGA GTTGAGG 60-50 DYS476 (TGA) ₇₋₁₃ 9.40 × 10⁻⁴ 1.35 × 10⁻⁴-3.12 × 1/0 1 1779 CGACTATGATTT AGCTGGGAAGTAC TD 7 [29] 10⁻³ GGGCTGTG TCAATGCTC 70-50 DYS477 (TTG) ₈₋₉ 3.91 × 10⁻⁴ 1.37 × 10⁻⁵-2.07 × 0/0 0 1765 TAACTTACAGAA AAGTGAATCGAGT TD 42 [29] 10⁻³ AAGCTCAGGG GCCTAGC 60-50 DYS478 (CAG)₄(CAA)₁(CAG)₈ 4.04 × 10⁻⁴ 1.46 × 10⁻⁵-2.17 × 0/0 0 1718 ACAGGCAACAA TCAGGATAAGCTA TD 20 [29] 10⁻³ ATTGGGTA GCAGTCTATG 60-50 DYS480 (TTA) ₆₋₁₀ 3.91 × 10⁻⁴ 1.44 × 10⁻⁵-2.09 × 0/0 0 1783 CCAGCACCTAG CAGCACTCCAAAA TD 9 [29] 10⁻³ GTTGAGGTA TGACAGA 70-50 DYS481 (CTT) ₂₂₋₃₂ 4.97 × 10⁻³ 2.36 × 10⁻³-9.03 × 3/5 8 1744 AGGAATGTGGC ACAGCTCACCAGA TD 12 [29] 10⁻³ TAACGCTGT AGGTTGC 70-50 DYS484 (AAT) ₁₀₋₁₆N₁₂(AAT)₃(TAT)₃ 2.61 × 10⁻³ 9.09 × 10⁻⁴-5.73 × 2/2 4 1792 CCTATCATCCGC CCTGGTTGACAAA TD 21 [29] 10⁻³ ATGGACTT GCCAGAT 60-50 DYS485 (TTT) ₀₋₁ (TTA) ₁₁₋₂₁ 4.04 × 10⁻⁴ 1.53 × 10⁻⁵-2.13 × 0/0 0 1730 AAAGCAGACTT AAAAATTAGCTGG TD 9 [29] 10⁻³ CGCCACTACA GCCTGGT 70-50 DYS487 (AAT) ₁₀₋₁₆ 1.77 × 10⁻³ 4.08 × 10⁻⁴-4.78 × 1/1 2 1511 TGTGGGAGGCCT CCTGGGCAACAGA TD 1 [29] 10⁻³ TAAGAAAA GAAAGAC 70-50 DYS488 (ATA) ₁₀₋₁₆ 4.40 × 10⁻⁴ 1.60 × 10⁻⁵-2.32 × 0/0 0 1576 GGGGAGGGATA TACCCTGGTCCAC TD 3 [29] 10⁻³ GCATTAGGA TTCAACC 70-50 DYS489 (TTA) ₁₀₋₁₅ 4.48 × 10⁻⁴ 1.66 × 10⁻⁵-2.38 × 0/0 0 1552 ACCCAAAGATTT AAAATTAGCCGAG TD 37 [29] 10⁻³ GTCGGCTA CATGGTG 70-50 DYS490 (TTA) ₈₋₁₆ 3.95 × 10⁻⁴ 1.48 × 10⁻⁵-2.10 × 0/0 0 1759 CCTGGCAGGAA GCAGAGCTTGCAC TD 10 [29] 10⁻³ TTATCCAGA TGAGCT 70-50 DYS491 (ATA) ₈₋₁₄ 4.09 × 10⁻⁴ 1.45 × 10⁻⁵-2.17 × 0/0 0 1706 GGAATGGGGAG GGAGAAAATTCA TD 15 [29] 10⁻³ GGATAACAT ATGCAGATACC 70-50 DYS492 (ATA) ₉₋₁₅ 3.92 × 10⁻⁴ 1.45 × 10⁻⁵-2.09 × 0/0 0 1770 AGATGAGCCAG AGTAGGGGTCAG TD 7 [29] 10⁻³ GCTTCAGAC GCACAATG 70-50 DYS493 (AAC) ₈₋₁₁ 3.86 × 10⁻⁴ 1.45 × 10⁻⁵-2.06 × 0/0 0 1800 ACTCCAGTCTGG CCCTGGGATTATA TD 36 [29] 10⁻³ GTGGACAG GGCATGA 70-50 DYS494 (TA) ₄₋₆ (TAA) ₇₋₁₁ 3.89 × 10⁻⁴ 1.43 × 10⁻⁵-2.07 × 0/0 0 1783 TTGCAACACTGT AACAAACCTGCAT TD 11 [29] 10⁻³ TCATTTGGA GTTCTTCAA 70-50 DYS495 (AAT) ₁₂₋₁₉ 2.09 × 10⁻³ 6.19 × 10⁻⁴-4.97 × 2/1 3 1755 CCCAGCTATTCA GCCAGAAAGTGTG TD 10 [29] 10⁻³ GGAGGTTG AGTCATCC 70-50 DYS497 (TTA) ₉₋₁₆ 1.49 × 10⁻³ 3.46 × 10⁻⁴-4.05 × 1/1 2 1786 AACATGTGCGTT GCATGTTGTGCAC TD 13 [29] 10⁻³ TTCAACCA ATGTAACC 70-50 DYS499 (TTG)₈ 3.93 × 10⁻⁴ 1.40 × 10⁻⁵-2.09 × 0/0 0 1771 TGGGTCAGAGA GGAGGAAGAGGT TD 47 [29] 10⁻³ AAGGATTGC TGCAATGA 70-50 DYS502 (AAT) ₄ (TGC) ₁ (CAT) ₆₋₉ 3.85 × 10⁻⁴ 1.43 × 10⁻⁵-2.05 × 0/0 0 1792 CAGCAAGCCAC TGTGCTTTTGGAG TD 34 [29] 10⁻³ CATACCATA TTTGGAG 70-50 DYS504 (CCTT) ₁₀₋₂₀N₇(CCCT)₃ 3.24 × 10⁻³ 1.26 × 10⁻³-6.62 × 1/4 5 1746 TCTACACCACTG GGCAACAGAGCA TD 8 [29] 10⁻³ TGCCAAGC ACCCTCT 70-50 DYS505 (TCCT) ₉₋₁₅ 1.51 × 10⁻³ 3.50 × 10⁻⁴-4.07 × 1/1 2 1760 TCTGGCGAAGTA TCGAGTCAGTTCA TD 6 [29] 10⁻³ ACCCAAAC CCAGAAGG 70-50 DYS508 (TATC) ₈₋₁₅ 3.03 × 10⁻³ 1.05 × 10⁻³-6.63 × 2/2 4 1544 ACAATGGCAAT GAACAAATAAGG TD 1 [29] 10⁻³ CCCAAATTC TGGGATGGAT 70-50 DYS509 (AAAT) ₇₋₁₁(AATAA)₁(AAAT)₃ 1.06 × 10⁻³ 1.55 × 10⁻⁴-3.53 × 0/1 1 1590 AACATGGTGAA TGTCCCCAGGGCT TD 37 [29] 10⁻³ TCCCTGTCTCT TTTTAAT 70-50 DYS510 (GATA)₃N₁₂ (GATA) ₉₋₁₅N₁₃(GGAT)₄ 5.99 × 10⁻³ 3.09 × 10⁻³-1.03 × 4/6 10 1779 TTTTTCCTCCCTT TCTGGAGAAGACA TD 34 [29] N₉(GATA)₃ 10⁻² ACCACAGA GAACTTGTCA 70-50 DYS511 (GATA) ₉₋₁₄ 1.52 × 10⁻³ 3.51 × 10⁻⁴-4.11 × 1/1 2 1760 GATAGGATGGG TGTGAATTCCCCT TD 13 [29] 10⁻³ GTGGATGTG TCTACATCTC 70-50 DYS512 (AGAT) ₇₋₁₃ 3.96 × 10⁻⁴ 1.44 × 10⁻⁵-2.11 × 0/0 0 1738 CACGCCCAGCT GGGAGGAATAAA TD 26 [29] 10⁻³ AATTTTTGT GGAAGGTTG 70-50 DYS513 (TCTA)₄(TCCA)₁(TATC)₃(CGTA)₁ 6.09 × 10⁻³ 3.14 × 10⁻³-1.05 × 6/4 10 1751 ATTGATCCATCC GTTGGATGAAGGG TD 32 [29] (TCTA) ₉₋₁₅ 10⁻² GTCTGTCC AGAGCAG 70-50 DYS516 (TTCT)₄N₃₀ (TTCT) ₉₋₁₈ 6.66 × 10⁻³ 3.55 × 10⁻³-1.12 × 7/4 11 1753 TTTCCAATGACC CGAACCTGCAAAT TD 22 [29] 10⁻² AAGACGTG TGTTCAC 60-50 DYS517 (AAAG) ₁₀₋₁₈N₈(AAAG)₃ 3.21 × 10⁻³ 1.25 × 10⁻³-6.62 × 3/2 5 1766 TAATCGTCCCAT TGCAATCCCAAAC TD 22 [29] 10⁻³ TTTGAGCA TCAGAAA 60-50 DYS518 (AAAG)₃(GAAG)₁ (AAAG) ₁₄₋₂₂(GGAG)₁ 1.84 × 10⁻² 1.25 × 10⁻²-2.60 ×  8/20 28 1556 GGCAACACAAG TCAGCTCTTACCA TD 54 [29] (AAAG)₄N₆ (AAAG) ₁₁₋₁₉N₂₇(AAGG)₄ 10⁻² TGAAACTGC TGGGTGAT 70-50 DYS520 (GATA) ₁₀₋₁₃ (CATA) ₁₀ ⁻¹¹ 2.66 × 10⁻³ 9.22 × 10⁻⁴-5.80 × 2/2 4 1760 AACAGCCTGCC ACCATCATGCCCT TD 24 [29] 10⁻³ CAACATAGT GCAATA 70-50 DYS521 (CTTT)₅(TCTT)₃(TTTT)₁(CTTT)₅T 9.54 × 10⁻⁴ 1.37 × 10⁻⁴-3.18 × 0/1 1 1751 GCCACAGCACC GCTGGGAGTGAG TD 24 [29] (CTTT) ₄₋₁₄ 10⁻³ TGTTCAGTA ACCCTGTA 70-50 DYS522 (ATAG) ₈₋₁₅ 1.04 × 10⁻³ 1.53 × 10⁻⁴-3.44 × 1/0 1 1620 CCTTTGAAATCA TCATAAACAGAGG TD 4 [29] 10⁻³ TTCATAATGC GTTCTGG 70-50 DYS525 (AGAT) ₈₋₁₃ 9.78 × 10⁻⁴ 1.42 × 10⁻⁴-3.26 × 0/1 1 1712 ATTCACACCATT CCATCTGTTTATC TD 2 [29] 10⁻³ GCACTCCA TTCCCATCA 70-50 DYS526a (CCTT) ₁₀₋₁₇ 2.72 × 10⁻³ 9.52 × 10⁻⁴-5.97 × 2/2 4 1716 TCTGGTGAACTG GGGTTACTTCGCC TD 51 [29] 10⁻³ ATCCAAACC AGAAGGT 65-50 DYS526b (CCCT)₃N₂₀ (CTTT) ₁₁₋₁₇ (CCTT) ₆₋₁₀N₁₁₃ 1.25 × 10⁻² 7.88 × 10⁻³-1.87 ×  9/11 20 1651 TCTGGTGAACTG GGGTTACTTCGCC TD 51 [29] (CCTT) ₁₀₋₁₇ 10⁻² ATCCAAACC AGAAGGT 65-50 DYS530 (AAAC) ₈₋₁₁ 3.94 × 10⁻⁴ 1.45 × 10⁻⁵-2.10 × 0/0 0 1760 CAGGGTCAAAA CTGCGGGACAATG TD 15 [29] 10⁻³ TCACCTTCC AAACAC 70-50 DYS531 (AAAT) ₉₋₁₃ 1.00 × 10⁻³ 1.45 × 10⁻⁴-3.50 × 0/1 1 1682 GACCCACTGGC TGCTCCCTTTCTTT TD 3 [29] 10⁻³ ATTCAAATC GTAGACG 70-50 DYS532 (TCCC)₃N₅(TTCC)₅N₉(TTCT)₃(TTCC)₁ 3.24 × 10⁻³ 1.13 × 10⁻³-7.10 × 3/1 4 1441 TTGGTTTTATGC TAGGTGACAGAGC TD 39 [29] (TTCT) ₆₋₁₇N₁₇(TTCT)₃N₁₃(TTCC)₄N₇₀ 10⁻³ CTTTCACT AGGATTC 70-50 (TTCT)₃N₆(TTCT)₃ DYS533 (TATC) ₉₋₁₄ 5.01 × 10⁻³ 2.39 × 10⁻³-9.11 × 4/4 8 1730 CATCTAACATCT TGATCAGTTCTTA TD 5 [29] 10⁻³ TTGTCATCTACC ACTCAACCA 70-50 DYS534 (CTTT)₃N₈ (CTTT) ₉₋₂₀N₉(CTTT)₃ 6.51 × 10⁻³ 3.44 × 10⁻³-1.10 × 9/2 11 1794 CATCTACCCAAC GACAAAGATGTTA TD 18 [29] 10⁻² ATCCATCTA GATGAATAGACA 60-50 DYS536 (TCCT) ₇₋₁₉N₈(TTCT)₄ 1.15 × 10⁻³ 1.66 × 10⁻⁴-3.83 × 1/0 1 1453 TTGCTTTTCTGC ATCGCATTCCCCT 52 53 [29] 10⁻³ TTCCCTTC CTCCTAC DYS537 (TCTA) ₈₋₁₃ 2.38 × 10⁻³ 7.12 × 10⁻⁴-5.70 × 2/1 3 1539 GGTCTCCAATTC TGGAACATGCCCA TD 3 [29] 10⁻³ CATCCAGA TTAATCA 70-50 DYS538 (GATA) ₉₋₁₃ 3.94 × 10⁻⁴ 1.47 × 10⁻⁵-2.10 × 0/0 0 1765 CCCCTGAATCAC AACCAGCCCAAAT TD 31 [29] 10⁻³ CAGAGTTC ACCCATC 70-50 DYS539 (TAGA) ₈₋₁₄ 1.00 × 10⁻³ 1.46 × 10⁻⁴-3.32 × 0/1 1 1676 GTTGAAGCCCTC GGTGCAGATCTCC TD 19 [29] 10⁻³ AATCTGGT CAAATTC 60-50 DYS540 (TTAT) ₉₋₁₄ 3.30 × 10⁻³ 1.28 × 10⁻³-6.79 × 2/3 5 1718 GACCGTGTACTC CAGGAGGCTAGCT TD 7 [29] 10⁻³ TGGCCAAT CAGGAGA 70-50 DYS541 (TATC) ₁₀₋₁₅(TTC)₁(TATC)₃ 3.92 × 10⁻³ 1.65 × 10⁻³-7.68 × 2/4 6 1700 TTCTATCTGTTC ACCTTTAAGAAGC TD 20 [29] 10⁻³ ATCCATCTAGG CTTCACC 60-50 DYS543 (AGAT)₃ (GATA) _(7.2-16)N₄₂ (ATGT) ₃₋₄ 7.10 × 10⁻³ 3.77 × 10⁻³-3.53 × 4/7 11 1645 CAAGGGCCAAT TGATCTTCCTGGT TD 23 [29] (ATGG) ₂₋₃N₃₅(GAAA)₃ 10⁻³ TATGTATGT CACTTTT 60-50 DYS544 (TAGA)₃N₁₅(TAGA)₃(TGGA)₁ (TAGA) ₆₋₁₂ 3.96 × 10⁻⁴ 1.44 × 10⁻⁵-1.20 × 0/0 0 1748 CTGGGCAACAG AATGCTGGCCAAA TD 32 [29] 10⁻² AGCAAGATT ACAAAGT 70-50 DYS545 (TGTT) ₈₋₁₁ 3.90 × 10⁻⁴ 1.39 × 10⁻⁵-2.09 × 0/0 0 1779 GAGGGGAGTGT GATCCAAGATGGT TD 30 [29] 10⁻³ AGAAAGAATGC GCCATTG 70-50 DYS546 (TTCC)₃N₂₃(TTCT)₃N₃₃(TTCC)₃N₁₆ 4.35 × 10⁻³ 1.85 × 10⁻³-8.56 × 2/4 6 1531 CCTGAGCTATTT TGCAGTACATCCT TD 35 [29] (TTCT) ₉₋₁₉ 10⁻³ TCCCTTTGC GGGGAAT 70-50 DYS547 (CCTT) ₉₋₁₃T(CTTC) ₄₋₅N₅₆ (TTTC) ₁₀₋₂₂ 2.36 × 10⁻² 1.70 × 10⁻²-3.18 × 22/17 39 1679 TCCATGTTACTG TGACAGAGCATAA TD 17 [29] N₁₀(CCTT)₄(TCTC)₁ (TTTC) ₉₋₁₆N₁₄ 10⁻² CAAAATACAC ACGTGTC 60-50 (TTTC)₃ DYS549 (GATA) ₉₋₁₅ 4.55 × 10⁻³ 2.05 × 10⁻³-8.58 × 1/6 7 1684 AACCAAATTCA GTCCCCTTTTCCA TD 15 [29] 10⁻³ GGGATGTACTGA TTTGTGA 70-50 DYS550 (AAGG)₄N₁₆(AAGG)₄(AAAG)₁ 3.87 × 10⁻⁴ 1.41 × 10⁻⁵-2.06 × 0/0 0 1794 GCCTGGGTAAC AGCTGAAAACTGT TD 34 [29] (AAGG) ₆₋₁₁ 10⁻³ AGGAGTGAA GCTGCTG 70-50 DYS551 (AGAT)₁₀₋₁₆N₈(AGAC)₃(AGGT)₁(AGAT)₄ 3.26 × 10⁻³ 1.26 × 10⁻³-6.72 × 1/4 5 1737 CCAGCCTGGGT AAAGTTCCTCCCA TD 38 [29] 10⁻³ GACAAAGTA GTTGCAC 70-50 DYS552 (TCTA)₃(TCTG)₁ (TCTA) ₇₋₁₂N₄₀ 2.69 × 10⁻³ 9.21 × 10⁻⁴-5.87 × 3/1 4 1742 CCATAGTGCCG AACACCTGATGCC TD 38 [29] (TCTA) ₁₁₋₁₆ 10⁻³ AGGTCAAGT TGGTTG 70-50 DYS554 (TAAA) ₈₋₁₁ 9.41 × 10⁻⁴ 1.36 × 10⁻⁴-3.15 × 1/0 1 1777 CTGGGCCACAG GGGCCAGTCTTTG TD 13 [29] 10⁻³ AGTGAGAC CAATATC 70-50 DYS556 (AAAT) ₈₋₁₂ 1.59 × 10⁻³ 3.70 × 10⁻⁴-4.30 × 1/1 2 1683 TGCTGTCACATC TTTGGTTGCTGAA TD 14 [29] 10⁻³ ACCAATGA GCATTGA 70-50 DYS557 (TTTC)₄(TTCTC)₁(TTTC)₄(TTC)₁ 3.80 × 10⁻³ 1.60 × 10⁻³-7.45 × 3/3 6 1758 TTTTCTGTGCCA TCTAATGCACCTT TD 21 [29] (TTTC) ₁₂₋₂₁ 10⁻³ AGCCTACA GAGGGATG 60-50 DYS558 (TTTG)₃ (TTTA) ₅₋₁₀ 3.98 × 10⁻⁴ 1.42 × 10⁻⁵-2.13 × 0/0 0 1741 GGTGGTCAGAA GCAGGCCAATATT TD 26 [29] 10⁻³ AATCCCTCA CACCATT 70-50 DYS559 (TAAA) ₇₋₉ 9.63 × 10⁻⁴ 1.40 × 10⁻⁴-3.19 × 1/0 1 1750 AGCCAAGGTCA TCGGTGAAGGCAC TD 25 [29] 10⁻³ TACCACTGC CAATAAT 70-50 DYS561 (GATA) ₉₋₁₃(GACA)₄ 9.41 × 10⁻⁴ 1.36 × 10⁻⁴-3.11 × 0/1 1 1783 GCCTGATGCCAT TGATCCCAACAAC TD 17 [29] 10⁻³ CTGAAAAT TGCACTC 60-50 DYS565 (ATAA) ₉₋₁₄ 2.09 × 10⁻³ 6.20 × 10⁻⁴-4.95 × 1/2 3 1757 AAACCCAGGAA CCTGGCTCAGCAC TD 11 [29] 10⁻³ GCAGTGTTG ATGAATA 70-50 DYS567 (ATAA) ₇₋₁₃ 4.08 × 10⁻⁴ 1.48 × 10⁻⁵-2.14 × 0/0 0 1713 GGAAGCTGAGG TTATGACCGGGAT TD 10 [29] 10⁻³ AAGGAGGAG CAAGTGC 70-50 DYS568 (AAAT) ₉₋₁₃ 1.08 × 10⁻³ 1.56 × 10⁻⁴-3.60 × 0/1 1 1547 GTGGCAGACAA TTGAAAAGGGATG TD 3 [29] 10⁻³ AACCCAGTT GGACTCA 70-50 DYS569 (ATTT) _(8.2-13) 1.58 × 10⁻³ 3.66 × 10⁻⁴-4.24 × 0/2 2 1696 TCCATGGGATAT GGCAGCCTGTAGG TD 12 [29] 10⁻³ GATGAGCA ACAGAGA 70-50 DYS570 (TTTC) ₁₄₋₂₄ 1.24 × 10⁻² 7.52 × 10⁻³-1.91 × 8/9 17 1426 GAACTGTCTACA TCAGCATAGTCAA TD 1 [29] 10⁻² ATGGCTCACG GAAACCAGACA 70-50 DYS571 (TTTTC)₄N₇ (TTTA) ₉₋₁₂ 4.13 × 10⁻⁴ 1.51 × 10⁻⁵-2.20 × 0/0 0 1682 AGCCTTCAGCG AGCTGAGATCATC TD 47 [29] 10⁻³ ACTGCTTTA CCATTGC 70-50 DYS572 (AAAT) ₈₋₁₃ 2.07 × 10⁻³ 6.17 × 10⁻⁴-4.96 × 0/3 3 1770 CTAAGGACGCC CTCATTCCCTATG TD 9 [29] 10⁻³ TCCCATACA GTTTGCAC 70-50 DYS573 (TTTA) ₈₋₁₃ 4.10 × 10⁻⁴ 1.51 × 10⁻⁵-2.17 × 0/0 0 1698 GGGGGAGAAAA AAAAATGGGGAG TD 14 [29] 10⁻³ AGTTTGGTG GTGGAAAT 70-50 DYS574 (TTAT) ₈₋₁₂ 9.77 × 10⁻⁴ 1.43 × 10⁻⁴-3.25 × 0/1 1 1721 GGTGGGGCTTCC AATGTAGACGACG TD 43 [29] 10⁻³ ATATTTTT GGTTGATG 60-50 DYS575 (AAAT) ₈₋₁₁ 3.91 × 10⁻⁴ 1.47 × 10⁻⁵-2.09 × 0/0 0 1764 GGTGGTGGACA AGTAATGGGATGC TD 11 [29] 10⁻³ TCCGTAATC TGGGTCA 70-50 DYS576 (AAAG) ₁₃₋₂₂ 1.43 × 10⁻² 9.41 × 10⁻³-2.07 × 12/12 24 1727 TTGGGCTGAGG GGCAGTCTCATTT TD 12 [29] 10⁻² AGTTCAATC CCTGGAG 70-50 DYS577 (ATTC) ₆₋₁₀ 4.11 × 10⁻⁴ 1.51 × 10⁻⁵-2.19 × 0/0 0 1691 TCAATGCATGTT GGAGGATGGTTTG TD 40 [29] 10⁻³ TTTCTACGTG AACCTGA 60-50 DYS578 (AAAT) ₇₋₁₀ 9.95 × 10⁻⁴ 1.43 × 10⁻⁴-3.30 × 1/0 1 1686 GAGGCGGAACT GCTTCAACAACCC TD 4 [29] 10⁻³ TTCAGTGAG TGGACAT 70-50 DYS579 (TATT) ₇₋₁₀ 3.94 × 10⁻⁴ 1.40 × 10⁻⁵-2.10 × 0/0 0 1755 GCCAGCAGTAG AGGCAGAGGTTGC TD 2 [29] 10⁻³ ACCCAGACT AGTGAGT 70-50 DYS580 (AATA) ₈₋₁₀ 4.05 × 10⁻⁴ 1.47 × 10⁻⁵-2.13 × 0/0 0 1725 GCAGTGAGCCG GGAGCAAACACT TD 4 [29] 10⁻³ AGATCAGG GCAATTTCC 70-50 DYS581 (TAGG) ₇₋₉ 3.84 × 10⁻⁴ 1.43 × 10⁻⁵-2.04 × 0/0 0 1807 GTAGGGTCTTGA CGAGCCAAGCTGC TD 36 [29] 10⁻³ ACAGCATACG TGTTAT 70-50 DYS583 (AAAC) ₇₋₉ 3.99 × 10⁻⁴ 1.44 × 10⁻⁵-2.12 × 0/0 0 1730 GCAGGAAAATT CCTCATCCAATAG TD 2 [29] 10⁻³ GCTTGAACC CTCTTCCT 70-50 DYS584 (CAAT) ₇₋₈ 3.90 × 10⁻⁴ 1.43 × 10⁻⁵-2.10 × 0/0 0 1777 TGCAGAATGTAT CTGCCAGTCTATT TD 45 [29] 10⁻³ GGTCTTTTTGA GCCCTTC 60-50 DYS585 (TTATG) ₈₋₁₂ 2.12 × 10⁻³ 6.33 × 10⁻⁴-5.06 × 2/1 3 1734 TGGAAGTATTCC CTCAAGTGGGGAA TD 42 [29] 10⁻³ ACTCACTTGCT GTCAAGG 60-50 DYS587 (CAATA) ₈₋₁₆[(CAGTA)₁(CAATA)₁]3 2.62 × 10⁻³ 9.16 × 10⁻⁴-5.75 × 2/2 4 1782 CCTAAAGCGAA TGAAGGCCAAAG TD 18 [29] 10⁻³ GAGACCATGA AGTGAAAGA 60-50 DYS588 (GCATT) ₉₋₁₆ 3.92 × 10⁻⁴ 1.47 × 10⁻⁵-2.10 × 0/0 0 1747 GAATGCAGAAC AGCCTGGGTGACA TD 42 [29] 10⁻³ CCTCAAGGA GAAACAC 60-50 DYS590 (TTTTG) ₅₋₉ 3.91 × 10⁻⁴ 1.45 × 10⁻⁵-2.06 × 0/0 0 1780 GGGAACATAGT GGGTGACAGAGC TD 5 [29] 10⁻³ CGGGCTGTA AAGAATCC 70-50 DYS593 (AAAAC)₄ (AAAAT) ₇₋₁₀ 1.51 × 10⁻³ 3.47 × 10⁻⁴-4.06 × 1/1 2 1775 CTTGAACCCAG TTATGCCCAAGTG TD 29 [29] 10⁻³ GAAGCAGAC ACACTGC 70-50 DYS594 (AAATA) ₈₋₁₃ 1.03 × 10⁻³ 1.46 × 10⁻⁴-3.41 × 1/0 1 1635 GATGTGCCTAAT CCCTGGTGTTAAT TD 5 [29] 10⁻³ GCCACAGA CGTGTCC 70-50 DYS595 (ATTTA) ₆₋₉ 3.96 × 10⁻⁴ 1.46 × 10⁻⁵-2.10 × 0/0 0 1750 TGTTTTCGGTTC AGGGGAACAACA TD 28 [29] 10⁻³ CTCTGTCC CACACTGG 70-50 DYS596 (GGA)₅(GTA)₁(GGA)₃(GAA)₃ 4.24 × 10⁻⁴ 1.52 × 10⁻⁵-2.28 × 0/0 0 1630 ATAACCGTGCCC TTTTGACAAGCCC TD 44 [29] [(GGA) ₁ (GAA) ₁ ] ₈₋₁₀ 10⁻³ TTTACTGC AAAGTTCT 60-50 DYS611 (TTC)₅N₉(TTC)₄(CTC)₁(TTC)₃N₉(TTC)₅ 8.89 × 10⁻³ 4.86 × 10⁻³-1.47 × 3/9 12 1426 TACAGGTGTGCA CTTGGCAACATAG TD 35 [29] (CTC)₁(TTC)₃N₁₅(TTC)₄(CT)₁(TTC)₃ 10⁻² CCATGAGG CAGATCC 70-50 (CTC)₁(TTC)₃ N₂₀(TTC)₃T(TTC)₄N₇ (TTC)₃N₉(TTC)₄(TCC)₁ (TTC) ₇₋₂₁N₂₃ (TTC)₄N₄ [(TTC)₁(CTC)₁]₂[(CTC)₁(TTC)₁]₃ DYS612 (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₁₉₋₃₁ 1.45 × 10⁻² 9.61 × 10⁻³-2.09 × 11/14 25 1767 CCCCCATGCCAG TGAGGGAAGGCA TD 42 [29] 10⁻² TAAGAATA AAAGAAAA 60-50 DYS613 (ATG)₈(ATA)₁ (ATG) ₈₋₉ 4.35 × 10⁻⁴ 1.60 × 10⁻⁵-2.32 × 0/0 0 1588 ATAGAAGGCAA AAAGTTAATGACG TD 23 [29] 10⁻³ ATTCTTTATCAA CCTTGTC 60-50 DYS614 (CTT)₄(CCT)₁(CTT)₃N₁₅(CCT)₄(CTT)₄(CCT)₁ 4.32 × 10⁻³ 1.94 × 10⁻³-8.14 × 2/5 7 1776 GTGGCGATGTTG GCCACCAAAAGGT TD 33 [29] (CTT)₃N₁₈(CCT)₃(CTT)₅N₂₀  10⁻³ TGAGTGTT TTTCAGA 70-50 [(CTT)₁(CTG)₁]₃ (CT)₁ (CTT) ₁₂₋₂₂N₈ (CTT)₄[(CTC)₁(CTT)₁]3 [(CTC)₁(TTT)₁](CTT)₅ DYS615 (TTG) ₇₋₈ 3.91 × 10⁻⁴ 1.43 × 10⁻⁵-2.09 × 0/0 0 1766 GGTCGAAGAAG TGATTCTGCTAAT TD 25 [29] 10⁻³ GTGTCACAGA TCCCATGC 70-50 DYS616 (TAT) ₈₋₁₆(CAT)₁(TAT)₃ 1.72 × 10⁻³ 4.03 × 10⁻⁴-4.64 × 1/1 2 1564 GGCAAACAGAT TTGTTCTGCCCAG TD 35 [29] 10⁻³ AGCAATTTACA CAGTAT 70-50 DYS617 (TTA) ₁₁₋₁₅ 4.13 × 10⁻⁴ 1.53 × 10⁻⁵-2.21 × 0/0 0 1684 AGCATGATGCCT GGATTGGGGAGTG TD 5 [29] 10⁻³ TCAGCTTT ATAGCAT 70-50 DYS618 (TAT) ₈₋₁₄ 3.95 × 10⁻⁴ 1.46 × 10⁻⁵-2.09 × 0/0 0 1766 CCCATACCCTTG GAGGGCTATGGG TD 13 [29] 10⁻³ GTGTTGTC AGGGATAG 70-50 DYS619 (AAT) ₆₋₁₀ 4.69 × 10⁻⁴ 1.70 × 10⁻⁵-2.50 × 0/0 0 1479 GGCGACAGAGC GGCATGTGAGTTG TD 16 [29] 10⁻³ GAGACTCTA AGGAACA 70-50 DYS620 (ATA) ₈₋₉ 4.11 × 10⁻⁴ 1.47 × 10⁻⁵-2.22 × 0/0 0 1678 TGACGAGTTAAT TGAGTTTGCTCCT TD 40 [29] 10⁻³ GGGTGCAG CTAGCTTTC 60-50 DYS621 (TTA) ₇₋₉ 4.44 × 10⁻⁴ 1.70 × 10⁻⁵-2.38 × 0/0 0 1543 GCCCAAATTAA TGACGAGTTAGTG TD 35 [29] 10⁻³ AAGGCACAA GGTGCAG 70-50 DYS622 (GAAA)₆(AGAAG)₁ (GAAA) ₈₋₁₆ 3.40 × 10⁻³ 1.32 × 10⁻³-7.01 × 2/3 5 1663 TCCAGCCTCGGT GGCTGAAGTGGGT TD 44 [29] 10⁻³ GATAAGAG TGTGTTA 60-50 DYS624 (GGAT) ₈₋₁₀ (G/AGAT)₁N₃₅(GGAT)₃ 4.06 × 10⁻⁴ 1.55 × 10⁻⁵-2.18 × 0/0 0 1699 GCATCTCAAATC TCCACCTGCTTTT TD 43 [29] 10⁻³ CTTTGTGGA CTCTTCA 60-50 DYS625 (CTTT)₄(TTCT)₁(CTTT)₃(TTT)₁(CTTT)₄ 9.58 × 10⁻⁴ 1.40 × 10⁻⁴-3.18 × 0/1 1 1746 TCATCACACATG GGCAAGTCACATG TD 22 [29] (TT)₁ (CTTT)₃N₄₇ (CTTT) ₃₋₅(CT)₁ 10⁻³ GCCTAATTG CATTACAA 60-50 (CTTT)₄(CCTT)₁ CTTT)₃N₁₀(CTTT)₃ DYS626 (GAAA) ₁₄₋₂₃N₂₄(GAAA)₃N₆(GAAA)₅ 1.22 × 10⁻² 7.70 × 10⁻³-1.82 × 13/7  20 1689 GCAAGACCCCA AAGAAGAATTTTG TD 23 [29] (AAA)₁ (GAAA) ₂₋₃(GAAG)₁(GAAA)₃ 10⁻² TAGCAAAAG GGACATGTTT 60-50 DYS627 (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₁₂₋₂₄N₈₁ 1.23 × 10⁻² 7.80 × 10⁻³-1.81 × 12/9  21 1766 CTAGGTGACAG GGATAATGAGCA TD 21 [29] (AAGG)₃ 10⁻² CGCAGGATT AATGGCAAG 60-50 DYS629 (TATC) ₅₋₁₂ 9.91 × 10⁻⁴ 1.41 × 10⁻⁴-3.31 × 1/0 1 1689 GGGATTATTACA TATGGGTAAATGG TD 19 [29] 10⁻³ ATTCAAGGTC CAAAAGT 60-50 DYS630 (AAAG)₄(AGAG)₃N₁₈ (AAAG) ₁₂₋₂₁ 4.86 × 10⁻³ 2.31 × 10⁻³-8.85 × 5/3 8 1784 GCCTTTGGACAG AGCCATGGAAAG TD 25 [29] 10⁻³ AGCAAGAC CTGTGAGT 70-50 DYS631 (AATA)₄(CATA)₁ (AATA) ₇₋₁₁ 9.77 × 10⁻⁴ 1.40 × 10⁻⁴-3.25 × 0/1 1 1721 CACTCCAGCCTC GCGCTCTGTGGAC TD 43 [29] 10⁻³ GGAGATAG ATTATCA 60-50 DYS632 (CATT) ₈₋₁₀ 3.97 × 10⁻⁴ 1.47 × 10⁻⁵-2.13 × 0/0 0 1745 GGCCGTTGCAA TCTGGGCAACAGA TD 24 [29] 10⁻³ AATAAACTG AGGAGAC 70-50 DYS633 (AAAT)₅N₁₆ (AAAT) ₇₋₉ 3.81 × 10⁻⁴ 1.38 × 10⁻⁵-2.02 × 0/0 0 1814 GGCAACAAGAG CCACCAGGGAAGT TD 46 [29] 10⁻³ CAAAACTCC GTCTTTC 60-50 DYS634 (GGAA)₆N₁₀ (AAGG) ₇₋₁₀N₁₂(AGGGG)₃ 4.20 × 10⁻⁴ 1.51 × 10⁻⁵-2.25 × 0/0 0 1646 TCAGAAGCATG TTGCTCCTTACAG TD 19 [29] 10⁻³ CTAGAACCCTA AAGAGGTGA 60-50 DYS635 (TCTA)₄(TGTA)₂(TCTA)₂(TGTA)₂ 3.85 × 10⁻³ 1.63 × 10⁻³-7.55 × 1/5 6 1732 Yfiler Yfiler Yfiler Yfiler [29] (TCTA)₂ (TATG) ₀₋₂ (TCTA) ₄₋₁₇ 10⁻³ DYS637 (AAAT)₄ (ACAT) ₈₋₁₄ 1.04 × 10⁻³ 1.53 × 10⁻⁴-3.42 × 0/1 1 1623 AAGCCAGTCAA TGCTGGGGTTGAA TD 41 [29] 10⁻³ CCAAACACA GGTAAAA 60-50 DYS638 (TTTA) ₈₋₁₃ 1.04 × 10⁻³ 1.47 × 10⁻⁴-3.45 × 1/0 1 1617 ACAATTTCCCTT CATGGTGGTAGGC TD 6 [29] 10⁻³ GGGGCTAC ACCTGTA 70-50 DYS640 (AAAT) ₉₋₁₃ 3.98 × 10⁻⁴ 1.41 × 10⁻⁵-2.16 × 0/0 0 1716 TGGGAAAAACC TAGGGTCAAGCCC TD 15 [29] 10⁻³ ATGAGATCC GTTCATA 70-50 DYS641 (TAAA) ₈₋₁₂ 3.90 × 10⁻⁴ 1.41 × 10⁻⁵-2.09 × 0/0 0 1768 CTTGAGCCCAG CCACACGATGCAA TD 6 [29] 10⁻³ GAAGCATAG TTTTGTC 70-50 DYS642 (TAAA) ₆₋₁₀ 3.91 × 10⁻⁴ 1.45 × 10⁻⁵-2.07 × 0/0 0 1785 CATTGTGCACGT AAAGGGTTGTGCT TD 33 [29] 10⁻³ GTACCCTAA GCATGAT 70-50 DYS643 (CTTTT) ₆₋₁₅ 1.50 × 10⁻³ 3.49 × 10⁻⁴-4.05 × 2/0 2 1773 AAGCCATGCCT TGTAACCAAACAC TD 14 [29] 10⁻³ GGTTAAACT CACCCATT 70-50 DYS644 (TTTTA) ₁₀₋₁₁ (TTTA) ₀₋₁ (TTTTA) ₀₋₁₃ 3.22 × 10⁻³ 1.25 × 10⁻³-6.62 × 3/2 5 1761 TGACTTCGGGGT CCTGGGCAAAAG TD 8 [29] 10⁻³ AGTTCCAG AGTGAGAC 70-50 DYS645 (TGTTT) ₇₋₉ 4.07 × 10⁻⁴ 1.49 × 10⁻⁵-2.14 × 0/0 0 1698 GGTTACGGGTG ACTGCCAGACTCA TD 40 [29] 10⁻³ GCAATCATA CACATGG 60-50 Y-GATA- (ATCT) ₁₁₋₁₆ 3.32 × 10⁻³ 1.25 × 10⁻³-6.80 × 3/2 5 1713 CCTGCCATCTCT ATAAATGGAGATA TD 41 [29] A10 10⁻³ ATTTATCTTGCA GTGGGTGGATT 60-50 TATA Y-GATA- (TAGA)₃N₁₂(TAGG)₃ (TAGA) ₈₋₁₅ 3.22 × 10⁻³ 1.28 × 10⁻³-6.62 × 1/4 5 1755 Yfiler Yfiler Yfiler Yfiler [29] H4 N₂₂(TAGA)₄ 10⁻³ Notes: The repeat nomenclature used is in accordance with rules defined by Kayser et al. (2004). Separation of repeat blocks by “N” represents the break point between the separate loci present within complex markers (as described in Methods and Materials). Repeat arrays observed to be variable through sequence analysis are highlighted in bold. The allele ranges given are those seen with the 1966 father-son pairs of European origin. The “Total number of Meioses” reported is the number of meioses for the marker, and is not the number of allele transmissions for multicopy markers. The mutations reported for the Yfiler loci have been previously reported in Reference 28.

PCR Protocols:

TD60-50 TD65-50 TD65-55 TD70-50 95 C. 10 min 95 C. 15 min 95 C. 10 min 95 C. 15 min 94 C. 30 s X10 94 C. 30 s X20 94 C. 30 s X10 94 C. 30 s X20 60-1 C.   30 s 65-1 C.   45 s 65-1 C.   30 s 70-1 C.   45 s 72 C. 45 s 72 C. 1 min 72 C. 45 s 72 C. 1 min 94 C. 30 s X25 94 C. 30 s X15 94 C. 30 s X25 94 C. 30 s X15 50 C. 30 s 50 C. 30 s 55 C. 30 s 50 C. 30 s 72 C. 45 s 72 C. 45 s 72 C. 45 s 72 C. 45 s 60 C. 45 min 60 C. 45 min 60 C. 45 min 60 C. 45 min 15 C. forever 15 C. forever 15 C. forever 15 C. forever

RM 1 RM 2 (DYS518, RM 3 (DYF403S1a/b, (DYF387S1, DYF399S1, DYS526a/b. DYF404S1, DYS449, DYS570, DYS576) DYS626, DYS627) DYS547, DYS612) PCR Buffer 1x PCR Buffer 1x PCR Buffer 1x MgCl₂ 2.27 mM MgCl₂ 1.5 mM MgCl₂ 2.0 mM dNTPs 220 μM dNTPs 250 μM dNTPs 250 μM DYF387S1 Primer 0.09 μM DYS518 Primer 0.5 μM DYF403S1a/b Primer 0.6 μM DYF399S1 Primer 0.36 μM DYS526a/b Primer 0.35 μM DYSF404S1 Primer 0.1 μM DYS570 Primer 0.09 μM DYS626 Primer 0.2 μM DYS449 Primer 0.1 μM DYS576 Primer 0.09 μM DYS627Primer 0.15 μM DYS547 Primer 0.6 μM DYS612 Primer 0.2 μM Taq 0.25 U Taq 0.35 U Taq 0.5 U DNA 2 ng DNA 2 ng DNA 2 ng PCR Protocol TD70-50 PCR Protocol TD65-55 PCR Protocol TD65-55

TABLE 2 Details of the 924 mutations observed. The repeat structure of both the father and son's alleles at the mutated Y-STR are given where possible. In the case of multicopy markers with multiple variable segments within the STR, total repeat numbers or amplicon size is given in the absence of sequence information. The age of the father at the time of the son's birth is given, as is an individual pair reference. Father's Father Locus Father Allele Son Allele Age Reference # DYF382S1 (GGAT) ₁₃(AGAT)₁(GGAT)₃N₈(GGAC)₃ (GGAT) ₁₄(AGAT)₁(GGAT)₃N₈(GGAC)₃ 59 1953 DYF386S1 (AAT) ₁₂ (AAT) ₁₃ 27 20 DYF386S1 (AAT) ₁₄ (AAT) ₁₃ 32 84 DYF386S1 (AAT) ₁₃ (AAT) ₁₂ 38 94 DYF386S1 (AAT) ₁₅ (AAT) ₁₃ 20 208 DYF386S1 (AAT) ₁₄ (AAT) ₁₃ 25 317 DYF386S1 (AAT) ₁₁ (AAT) ₁₂ 19 641 DYF386S1 (AAT) ₁₄ (AAT) ₁₃ 27 1195 DYF386S1 (AAT) ₁₄ (AAT) ₁₅ 40 1558 DYF386S1 (AAT) ₁₄ (AAT) ₁₃ 42 1644 DYF386S1 (AAT) ₁₄ (AAT) ₁₃ 52 1864 DYF387S1 21 24 21 46 DYF387S1 23 22 48 74 DYF387S1 23 24 36 150 DYF387S1 20 21 29 155 DYF387S1 24 23 24 259 DYF387S1 22 21 28 677 DYF387S1 24 23 40 738 DYF387S1 25 24 22 817 DYF387S1 25 26 36 830 DYF387S1 25 26 18 852 DYF387S1 23 24 28 880 DYF387S1 24 23 19 916 DYF387S1 21 22 33 955 DYF387S1 22 23 43 1159 DYF387S1 23 24 Unknown 1202 DYF387S1 24 23 30 1274 DYF387S1 23 22 37 1319 DYF387S1 23 21 Unknown 1328 DYF387S1 24 25 31 1390 DYF387S1 23 24 39 1451 DYF387S1 22 21 24 1469 DYF387S1 22 23 38 1494 DYF387S1 21 22 39 1552 DYF387S1 21 22 20 1592 DYF387S1 23 22 42 1644 DYF387S1 23 22 23 1710 DYF387S1 23 22 18 1750 DYF387S1 23 25 54 1911 DYF388S1 (CTTC)₆ (CTTT) ₁₂N₁₈(CTTC)₃(TTTC)₁ (CTTC)₆ (CTTT) ₁₃N₁₈(CTTC)₃(TTTC)₁ 37 36 (CTTC)₃N₈(CTTC)₃N₃₂(CTTC)₃ (CTTC)₃N₈(CTTC)₃N₃₂(CTTC)₃ DYF388S1 (CTTC)₆ (CTTT) ₁₄N₁₈(CTTC)₃(TTTC)₁ (CTTC)₆ (CTTT) ₁₂N₁₈(CTTC)₃(TTTC)₁ 34 372 (CTTC)₃N₈(CTTC)₃N₃₂(CTTC)₃ (CTTC)₃N₈(CTTC)₃N₃₂(CTTC)₃ DYF388S1 (CTTC)₆ (CTTT) ₁₂N₁₈(CTTC)₃(TTTC)₁ (CTTC)₆ (CTTT) ₁₃N₁₈(CTTC)₃(TTTC)₁ 28 674 (CTTC)₃N₈(CTTC)₃N₃₂(CTTC)₃ (CTTC)₃N₈(CTTC)₃N₃₂(CTTC)₃ DYF388S1 (CTTC)₆ (CTTT) ₁₂N₁₈(CTTC)₃(TTTC)₁ (CTTC)₆ (CTTT) ₁₃N₁₈(CTTC)₃(TTTC)₁ 21 769 (CTTC)₃N₈(CTTC)₃N₃₂(CTTC)₃ (CTTC)₃N₈(CTTC)₃N₃₂(CTTC)₃ DYF388S1 (CTTC)₆ (CTTT) ₁₁N₁₈(CTTC)₃(TTTC)₁ (CTTC)₆ (CTTT) ₁₂N₁₈(CTTC)₃(TTTC)₁ 49 945 (CTTC)₃N₈(CTTC)₃N₃₂(CTTC)₃ (CTTC)₃N₈(CTTC)₃N₃₂(CTTC)₃ DYF388S1 (CTTC)₆ (CTTT) ₁₂N₁₈(CTTC)₃(TTTC)₁ (CTTC)₆ (CTTT) ₁₁N₁₈(CTTC)₃(TTTC)₁ 28 1035 (CTTC)₃N₈(CTTC)₃N₃₂(CTTC)₃ (CTTC)₃N₈(CTTC)₃N₃₂(CTTC)₃ DYF388S1 (CTTC)₆ (CTTT) ₁₂N₁₈(CTTC)₃(TTTC)₁ (CTTC)₆ (CTTT) ₁₃N₁₈(CTTC)₃(TTTC)₁ 30 1177 (CTTC)₃N₈(CTTC)₃N₃₂(CTTC)₃ (CTTC)₃N₈(CTTC)₃N₃₂(CTTC)₃ DYF388S1 (CTTC)₆ (CTTT) ₁₃N₁₈(CTTC)₃(TTTC)₁ (CTTC)₆ (CTTT) ₁₂N₁₈(CTTC)₃(TTTC)₁ 56 1272 (CTTC)₃N₈(CTTC)₃N₃₂(CTTC)₃ (CTTC)₃N₈(CTTC)₃N₃₂(CTTC)₃ DYF388S1 (CTTC)₆ (CTTT) ₁₃N₁₈(CTTC)₃(TTTC)₁ (CTTC)₆ (CTTT) ₁₂N₁₈(CTTC)₃(TTTC)₁ Unknown 1352 (CTTC)₃N₈(CTTC)₃N₃₂(CTTC)₃ (CTTC)₃N₈(CTTC)₃N₃₂(CTTC)₃ DYF388S1 (CTTC)₆ (CTTT) ₁₃N₁₈(CTTC)₃(TTTC)₁ (CTTC)₆ (CTTT) ₁₂N₁₈(CTTC)₃(TTTC)₁ 31 1518 (CTTC)₃N₈(CTTC)₃N₃₂(CTTC)₃ (CTTC)₃N₈(CTTC)₃N₃₂(CTTC)₃ DYF388S1 (CTTC)₆ (CTTT) ₁₄N₁₈(CTTC)₃(TTTC)₁ (CTTC)₆ (CTTT) ₁₂N₁₈(CTTC)₃(TTTC)₁ 28 1734 (CTTC)₃N₈(CTTC)₃N₃₂(CTTC)₃ (CTTC)₃N₈(CTTC)₃N₃₂(CTTC)₃ DYF390S1 (TTTA) ₁₁ (TTTA) ₁₀ 21 1667 DYF393S1 (AAG)₄(AA)₁ (AAG) ₂₆(CAG)₁ (AAG)₄(AA)₁ (AAG) ₂₅(CAG)₁ 32 19 DYF393S1 (AAG)₄(AA)₁ (AAG) ₂₈(CAG)₁ (AAG)₄(AA)₁ (AAG) ₂₉(CAG)₁ 32 84 DYF393S1 (AAG)₄(AA)₁ (AAG) ₁₉(CAG)₁ (AAG)₄(AA)₁ (AAG) ₂₀(CAG)₁ 34 183 DYF393S1 (AAG)₄(AA)₁ (AAG) ₂₆(CAG)₁ (AAG)₄(AA)₁ (AAG) ₂₅(CAG)₁ 32 213 DYF393S1 (AAG)₄(AA)₁ (AAG) ₂₅(CAG)₁ (AAG)₄(AA)₁ (AAG) ₂₄(CAG)₁ 26 303 DYF393S1 (AAG)₄(AA)₁ (AAG) ₂₂(CAG)₁ (AAG)₄(AA)₁ (AAG) ₂₃(CAG)₁ 31 927 DYF393S1 (AAG)₄(AA)₁ (AAG) ₂₆(CAG)₂ (AAG)₄(AA)₁ (AAG) ₂₇(CAG)₂ 23 941 DYF393S1 (AAG)₄(AA)₁ (AAG) ₂₂(CAG)₁ (AAG)₄(AA)₁ (AAG) ₂₃(CAG)₁ 64 951 DYF393S1 (AAG)₄(AA)₁ (AAG) ₂₇(CAG)₁ (AAG)₄(AA)₁ (AAG) ₂₆(CAG)₁ 21 1207 DYF393S1 (AAG)₄(AA)₁ (AAG) ₂₂(CAG)₁ (AAG)₄(AA)₁ (AAG) ₂₄(CAG)₁ 17 1406 DYF393S1 (AAG)₄(AA)₁ (AAG) ₂₈(CAG)₁ (AAG)₄(AA)₁ (AAG) ₂₉(CAG)₁ 19 1530 DYF393S1 (AAG)₄(AA)₁ (AAG) ₂₇(CAG)₁ (AAG)₄(AA)₁ (AAG) ₂₈(CAG)₁ 26 1551 DYF393S1 (AAG)₄(AA)₁ (AAG) ₂₃(CAG)₁ (AAG)₄(AA)₁ (AAG) ₂₄(CAG)₁ 36 1672 DYF393S1 (AAG)₄(AA)₁ (AAG) ₂₅(CAG)₁ (AAG)₄(AA)₁ (AAG) ₂₄(CAG)₁ 55 1928 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₈ (GAAA) ₂₀ 22 14 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₆ (GAAA)₃N₈ (GAAA) ₁₇ 46 21 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₈ (GAAA) ₂₀ 36 22 DYF399S1 (GAAA)₃N₇ (GAAA) ₁₈ (GAAA)₃N₈ (GAAA) ₁₉ 30 25 DYF399S1 (GAAA)₃N₇ (GAAA) ₂₁ (GAAA)₃N₈ (GAAA) ₂₀ 32 32 DYF399S1 (GAAA)₃N₈ (GAAA) ₂₀ (GAAA)₃N₈ (GAAA) ₁₉ 16 55 DYF399S1 (GAAA)₃N₇ (GAAA) ₁₈ (GAAA)₃N₈ (GAAA) ₁₉ 32 59 DYF399S1 (GAAA)₃N₈ (GAAA) ₂₀ (GAAA)₃N₈ (GAAA) ₁₉ 30 62 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₇ (GAAA) ₁₈ 46 72 DYF399S1 (GAAA)₃N₇ (GAAA) ₁₈ (GAAA)₃N₈ (GAAA) ₁₉ 46 72 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₈ (GAAA) ₂₀ 25 79 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₈ (GAAA) ₂₀ 25 80 DYF399S1 (GAAA)₃N₈ (GAAA) ₂₀ (GAAA)₃N₈ (GAAA) ₁₉ 28 91 DYF399S1 (GAAA)₃N₇ (GAAA) ₂₁ (GAAA)₃N₈ (GAAA) ₂₀ 32 95 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₇ (GAAA)₃N₈ (GAAA) ₁₆ 30 99 DYF399S1 (GAAA)₃N₈ (GAAA) ₂₀ (GAAA)₃N₈ (GAAA) ₁₉ 27 119 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₈ (GAAA) ₂₀ 48 122 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₇ (GAAA) ₁₈ 33 126 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₇ (GAAA)₃N₈ (GAAA) ₁₆ 36 136 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₈ (GAAA) ₂₀ 28 153 DYF399S1 (GAAA)₃N₇ (GAAA) ₁₈ (GAAA)₃N₈ (GAAA) ₁₇ 33 189 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₇ (GAAA)₃N₇ (GAAA) ₁₈ 39 200 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₆ (GAAA)₃N₈ (GAAA) ₁₅ 22 203 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₇ (GAAA) ₁₈ 22 229 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₆ (GAAA)₃N₈ (GAAA) ₁₅ 50 270 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₈ (GAAA) ₂₀ 28 287 DYF399S1 (GAAA)₃N₇ (GAAA) ₂₁ (GAAA)₃N₈ (GAAA) ₂₀ 32 290 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₆ (GAAA)₃N₈ (GAAA) ₁₇ 21 299 DYF399S1 (GAAA)₃N₈ (GAAA) ₂₂ (GAAA)₃N₇ (GAAA) ₂₁ 27 302 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₅ (GAAA)₃N₈ (GAAA) ₁₆ 38 336 DYF399S1 (GAAA)₃N₇ (GAAA) ₁₈ (GAAA)₃N₈ (GAAA) ₁₇ 50 356 DYF399S1 (GAAA)₃N₇ (GAAA) ₂₁ (GAAA)₃N₈ (GAAA) ₂₂ 28 367 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₆ (GAAA)₃N₈ (GAAA) ₁₇ 34 372 DYF399S1 (GAAA)₃N₇ (GAAA) ₂₁ (GAAA)₃N₈ (GAAA) ₂₂ 28 373 DYF399S1 (GAAA)₃N₇ (GAAA) ₁₈ (GAAA)₃N₈ (GAAA) ₁₇ 35 389 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₆ (GAAA)₃N₈ (GAAA) ₁₇ 32 401 DYF399S1 (GAAA)₃N₇ (GAAA) ₁₈ (GAAA)₃N₈ (GAAA) ₁₇ 53 453 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₇ (GAAA)₃N₇ (GAAA) ₁₈ 34 459 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₇ (GAAA)₃N₈ (GAAA) ₁₆ 26 480 DYF399S1 (GAAA)₃N₇ (GAAA) ₁₈ (GAAA)₃N₈ (GAAA) ₁₉ 28 484 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₇ (GAAA) ₁₈ 26 488 DYF399S1 (GAAA)₃N₇ (GAAA) ₂₁ (GAAA)₃N₈ (GAAA) ₂₀ 39 492 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₈ (GAAA) ₂₀ 27 494 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₈ (GAAA) ₂₀ 35 500 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₆ (GAAA)₃N₈ (GAAA) ₁₅ 19 546 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₈ (GAAA) ₂₀ 34 559 DYF399S1 (GAAA)₃N₇ (GAAA) ₂₁ (GAAA)₃N₈ (GAAA) ₂₂ 30 586 DYF399S1 (GAAA)₃N₈ (GAAA) ₂₀ (GAAA)₃N₈ (GAAA) ₁₉ 29 603 DYF399S1 (GAAA)₃N₇ (GAAA) ₁₈ (GAAA)₃N₈ (GAAA) ₁₇ 56 608 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₇ (GAAA) ₁₈ 32 614 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₇ (GAAA)₃N₈ (GAAA) ₁₆ 43 624 DYF399S1 (GAAA)₃N₈ (GAAA) ₂₀ (GAAA)₃N₈ (GAAA) ₁₉ 25 630 DYF399S1 (GAAA)₃N₇ (GAAA) ₂₁ (GAAA)₃N₈ (GAAA) ₂₀ 30 640 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₇ (GAAA) ₁₈ 43 657 DYF399S1 (GAAA)₃N₈ (GAAA) ₂₂ (GAAA)₃N₇ (GAAA) ₂₁ 25 666 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₈ (GAAA) ₂₀ 23 675 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₇ (GAAA) ₁₈ 18 680 DYF399S1 (GAAA)₃N₇ (GAAA) ₁₈ (GAAA)₃N₈ (GAAA) ₁₉ 23 687 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₇ (GAAA)₃N₇ (GAAA) ₁₈ 20 706 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₈ (GAAA) ₂₀ 33 718 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₅ (GAAA)₃N₈ (GAAA) ₁₆ 21 720 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₅ (GAAA)₃N₈ (GAAA) ₁₄ 22 747 DYF399S1 (GAAA)₃N₈ (GAAA) ₂₀ (GAAA)₃N₈ (GAAA) ₁₉ 28 772 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₆ (GAAA)₃N₈ (GAAA) ₁₅ 28 805 DYF399S1 (GAAA)₃N₈ (GAAA) ₂₂ (GAAA)₃N₈ (GAAA) ₂₀ 22 817 DYF399S1 (GAAA)₃N₇ (GAAA) ₂₁ (GAAA)₃N₈ (GAAA) ₂₀ 20 824 DYF399S1 (GAAA)₃N₈ (GAAA) ₂₀ (GAAA)₃N₈ (GAAA) ₁₉ 20 827 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₇ (GAAA) ₁₈ 25 877 DYF399S1 (GAAA)₃N₈ (GAAA) ₂₀ (GAAA)₃N₈ (GAAA) ₁₉ 31 881 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₇ (GAAA) ₁₈ 19 900 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₆ (GAAA)₃N₈ (GAAA) ₁₇ 37 904 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₅ (GAAA)₃N₈ (GAAA) ₁₄ 34 911 DYF399S1 (GAAA)₃N₇ (GAAA) ₁₈ (GAAA)₃N₈ (GAAA) ₁₇ 19 916 DYF399S1 (GAAA)₃N₇ (GAAA) ₁₈ (GAAA)₃N₈ (GAAA) ₁₆ 24 926 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₇ (GAAA) ₁₈ 22 986 DYF399S1 (GAAA)₃N₈ (GAAA) ₂₀ (GAAA)₃N₇ (GAAA) ₂₁ 36 989 DYF399S1 (GAAA)₃N₇ (GAAA) ₁₈ (GAAA)₃N₈ (GAAA) ₁₇ 35 1001 DYF399S1 (GAAA)₃N₇ (GAAA) ₂₁ (GAAA)₃N₈ (GAAA) ₂₀ 41 1008 DYF399S1 (GAAA)₃N₈ (GAAA) ₂₀ (GAAA)₃N₈ (GAAA) ₁₉ 41 1008 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₆ (GAAA)₃N₈ (GAAA) ₁₅ 33 1046 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₅ (GAAA)₃N₈ (GAAA) ₁₆ 33 1046 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₇ (GAAA) ₁₈ 31 1072 DYF399S1 (GAAA)₃N₈ (GAAA) ₂₀ (GAAA)₃N₈ (GAAA) ₁₉ 22 1088 DYF399S1 (GAAA)₃N₇ (GAAA) ₁₈ (GAAA)₃N₈ (GAAA) ₁₉ 36 1091 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₅ (GAAA)₃N₈ (GAAA) ₁₆ 23 1095 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₇ (GAAA)₃N₇ (GAAA) ₁₈ 25 1104 DYF399S1 (GAAA)₃N₈ (GAAA) ₂₀ (GAAA)₃N₈ (GAAA) ₁₉ 43 1138 DYF399S1 (GAAA)₃N₇ (GAAA) ₁₈ (GAAA)₃N₈ (GAAA) ₁₇ 20 1154 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₇ (GAAA)₃N₈ (GAAA) ₁₆ 36 1155 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₆ (GAAA)₃N₈ (GAAA) ₁₇ 34 1158 DYF399S1 (GAAA)₃N₈ (GAAA) ₂₂ (GAAA)₃N₇ (GAAA) ₂₁ 34 1158 DYF399S1 (GAAA)₃N₇ (GAAA) ₁₈ (GAAA)₃N₈ (GAAA) ₁₇ 43 1159 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₃ (GAAA)₃N₈ (GAAA) ₁₄ 21 1163 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₇ (GAAA) ₁₈ 21 1207 DYF399S1 (GAAA)₃N₇ (GAAA) ₂₁ (GAAA)₃N₈ (GAAA) ₂₀ Unknown 1263 DYF399S1 (GAAA)₃N₇ (GAAA) ₁₈ (GAAA)₃N₈ (GAAA) ₁₉ Unknown 1265 DYF399S1 (GAAA)₃N₈ (GAAA) ₂₀ (GAAA)₃N₈ (GAAA) ₁₉ Unknown 1268 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₇ (GAAA)₃N₈ (GAAA) ₁₆ 39 1327 DYF399S1 (GAAA)₃N₇ (GAAA) ₂₁ (GAAA)₃N₈ (GAAA) ₂₀ 27 1397 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₄ (GAAA)₃N₈ (GAAA) ₁₃ 42 1407 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₇ (GAAA) ₁₈ 42 1411 DYF399S1 (GAAA)₃N₈ (GAAA) ₂₂ (GAAA)₃N₇ (GAAA) ₂₁ 40 1443 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₇ (GAAA)₃N₈ (GAAA) ₁₆ 17 1446 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₇ (GAAA)₃N₈ (GAAA) ₁₆ 24 1455 DYF399S1 (GAAA)₃N₇ (GAAA) ₁₈ (GAAA)₃N₈ (GAAA) ₁₉ 18 1456 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₅ (GAAA)₃N₈ (GAAA) ₁₆ 24 1466 DYF399S1 (GAAA)₃N₈ (GAAA) ₂₀ (GAAA)₃N₇ (GAAA) ₂₁ 24 1466 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₇ (GAAA)₃N₇ (GAAA) ₁₈ 39 1471 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₄ (GAAA)₃N₈ (GAAA) ₁₅ Unknown 1479 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₇ (GAAA) ₁₈ 28 1554 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₈ (GAAA) ₂₀ 37 1577 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₇ (GAAA)₃N₇ (GAAA) ₁₈ 40 1606 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₇ (GAAA) ₁₈ 25 1612 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₇ (GAAA)₃N₈ (GAAA) ₁₆ 17 1620 DYF399S1 (GAAA)₃N₈ (GAAA) ₂₀ (GAAA)₃N₈ (GAAA) ₁₉ Unknown 1650 DYF399S1 (GAAA)₃N₇ (GAAA) ₁₈ (GAAA)₃N₈ (GAAA) ₁₉ 24 1651 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₇ (GAAA) ₁₈ 24 1658 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₄ (GAAA)₃N₈ (GAAA) ₁₅ 37 1663 DYF399S1 (GAAA)₃N₈ (GAAA) ₂₂ (GAAA)₃N₇ (GAAA) ₂₁ 32 1664 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₆ (GAAA)₃N₈ (GAAA) ₂₀ 17 1665 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₅ (GAAA)₃N₈ (GAAA) ₁₄ 20 1670 DYF399S1 (GAAA)₃N₇ (GAAA) ₁₈ (GAAA)₃N₈ (GAAA) ₁₉ 34 1691 DYF399S1 (GAAA)₃N₈ (GAAA) ₂₀ (GAAA)₃N₇ (GAAA) ₂₁ 28 1696 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₇ (GAAA) ₁₈ 23 1722 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₆ (GAAA)₃N₈ (GAAA) ₁₇ 30 1733 DYF399S1 (GAAA)₃N₈ (GAAA) ₂₀ (GAAA)₃N₇ (GAAA) ₂₁ 26 1760 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₇ (GAAA)₃N₇ (GAAA) ₁₈ 29 1773 DYF399S1 (GAAA)₃N₈ (GAAA) ₂₀ (GAAA)₃N₈ (GAAA) ₁₉ 31 1798 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₅ (GAAA)₃N₈ (GAAA) ₁₆ 51 1813 DYF399S1 (GAAA)₃N₇ (GAAA) ₂₁ (GAAA)₃N₈ (GAAA) ₂₀ 19 1841 DYF399S1 (GAAA)₃N₈ (GAAA) ₂₂ (GAAA)₃N₇ (GAAA) ₂₁ 55 1844 DYF399S1 (GAAA)₃N₈ (GAAA) ₂₂ (GAAA)₃N₈ (GAAA) ₂₃ 59 1867 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₇ (GAAA)₃N₈ (GAAA) ₁₆ 53 1869 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₆ (GAAA)₃N₈ (GAAA) ₁₅ 73 1884 DYF399S1 (GAAA)₃N₇ (GAAA) ₁₈ (GAAA)₃N₈ (GAAA) ₁₉ 52 1891 DYF399S1 (GAAA)₃N₇ (GAAA) ₂₁ (GAAA)₃N₈ (GAAA) ₂₀ 52 1891 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₆ (GAAA)₃N₈ (GAAA) ₁₅ 55 1909 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₉ (GAAA)₃N₇ (GAAA) ₁₈ 60 1913 DYF399S1 (GAAA)₃N₈ (GAAA) ₁₇ (GAAA)₃N₈ (GAAA) ₁₆ 50 1941 DYF401S1 (AAGG)₃(AAGC)₁(AAGG)₃N₃₉(AAGG)₃N₈(AAGG)₃ (AAGG)₃(AAGC)₁(AAGG)₃N₃₉(AAGG)₃N₈(AAGG)₃ 37 36 (AAAG)₁(AAGG)₃N₁₃ (AAAG) ₁₅G(AAGG)₆ (AAAG)₁(AAGG)₃N₁₃ (AAAG) ₁₆G(AAGG)₆ DYF401S1 (AAGG)₃(AAGC)₁(AAGG)₃N₃₉(AAGG)₃N₈(AAGG)₃ (AAGG)₃(AAGC)₁(AAGG)₃N₃₉(AAGG)₃N₈(AAGG)₃ 34 372 (AAAG)₁(AAGG)₃N₁₃ (AAAG) ₁₇G(AAGG)₆ (AAAG)₁(AAGG)₃N₁₃ (AAAG) ₁₅G(AAGG)₆ DYF401S1 (AAGG)₃(AAGC)₁(AAGG)₃N₃₉(AAGG)₃N₈(AAGG)₃ (AAGG)₃(AAGC)₁(AAGG)₃N₃₉(AAGG)₃N₈(AAGG)₃ 28 674 (AAAG)₁(AAGG)₃N₁₃ (AAAG) ₁₅G(AAGG)₆ (AAAG)₁(AAGG)₃N₁₃ (AAAG) ₁₆G(AAGG)₆ DYF401S1 (AAGG)₃(AAGC)₁(AAGG)₃N₃₉(AAGG)₃N₈(AAGG)₃ (AAGG)₃(AAGC)₁(AAGG)₃N₃₉(AAGG)₃N₈(AAGG)₃ 21 769 (AAAG)₁(AAGG)₃N₁₃ (AAAG) ₁₅G(AAGG)₆ (AAAG)₁(AAGG)₃N₁₃ (AAAG) ₁₆G(AAGG)₆ DYF401S1 (AAGG)₃(AAGC)₁(AAGG)₃N₃₉(AAGG)₃N₈(AAGG)₃ (AAGG)₃(AAGC)₁(AAGG)₃N₃₉(AAGG)₃N₈(AAGG)₃ Unknown 1241 (AAAG)₁(AAGG)₃N₁₃ (AAAG) ₁₅G(AAGG)₆ (AAAG)₁(AAGG)₃N₁₃ (AAAG) ₁₄G(AAGG)₆ DYF401S1 (AAGG)₃(AAGC)₁(AAGG)₃N₃₉(AAGG)₃N₈(AAGG)₃ (AAGG)₃(AAGC)₁(AAGG)₃N₃₉(AAGG)₃N₈(AAGG)₃ 56 1272 (AAAG)₁(AAGG)₃N₁₃ (AAAG) ₁₆G(AAGG)₆ (AAAG)₁(AAGG)₃N₁₃ (AAAG) ₁₅G(AAGG)₆ DYF401S1 (AAGG)₃(AAGC)₁(AAGG)₃N₃₉(AAGG)₃N₈(AAGG)₃ (AAGG)₃(AAGC)₁(AAGG)₃N₃₉(AAGG)₃N₈(AAGG)₃ 31 1518 (AAAG)₁(AAGG)₃N₁₃ (AAAG) ₁₆G(AAGG)₆ (AAAG)₁(AAGG)₃N₁₃ (AAAG) ₁₅G(AAGG)₆ DYF401S1 (AAGG)₃(AAGC)₁(AAGG)₃N₃₉(AAGG)₃N₈(AAGG)₃ (AAGG)₃(AAGC)₁(AAGG)₃N₃₉(AAGG)₃N₈(AAGG)₃ 28 1734 (AAAG)₁(AAGG)₃N₁₃ (AAAG) ₁₇G(AAGG)₆ (AAAG)₁(AAGG)₃N₁₃ (AAAG) ₁₅G(AAGG)₆ DYF403S1a 342 338 20 73 DYF403S1a 321 316 32 128 DYF403S1a 316 321 27 132 DYF403S1a 316, 329, 338 321, 325, 334 17 175 DYF403S1a 346 350 37 186 DYF403S1a 342 346 22 201 DYF403S1a 354 350 37 406 DYF403S1a 350 354 20 423 DYF403S1a 342 346 19 546 DYF403S1a 325 329 24 681 DYF403S1a 325 321 39 749 DYF403S1a 334 338 22 817 DYF403S1a 321 342 28 841 DYF403S1a 338 342 37 904 DYF403S1a 308 312 34 911 DYF403S1a 342 346 18 943 DYF403S1a 312 316 20 977 DYF403S1a 342 346 46 1033 DYF403S1a 321 316 21 1053 DYF403S1a 350 354 39 1071 DYF403S1a 342 346 27 1085 DYF403S1a 325 329 44 1110 DYF403S1a 342 338 22 1323 DYF403S1a 346 350 36 1336 DYF403S1a 312 316 Unknown 1353 DYF403S1a 354 350 45 1364 DYF403S1a 342 338 44 1378 DYF403S1a 342 338 42 1411 DYF403S1a 346 350 42 1441 DYF403S1a 338 342 24 1480 DYF403S1a 325 329 40 1531 DYF403S1a 346 342 28 1554 DYF403S1a 312 316 33 1561 DYF403S1a 321 316 25 1634 DYF403S1a 342 334 36 1643 DYF403S1a 329 334 24 1704 DYF403S1a 312 316 26 1725 DYF403S1a 312 316 40 1785 DYF403S1a 312 316 31 1798 DYF403S1a 329 334 43 1818 DYF403S1a 346 342 27 1840 DYF403S1a 346 350 43 1883 DYF403S1a 329 334 57 1896 DYF403S1a 334 321 64 1912 DYF403S1a 346 342 50 1941 DYF403S1a 325, 346 329, 339 56 1947 DYF403S1b  50  49 40 28 DYF403S1b  46.1  45.1 32 115 DYF403S1b  50  49 33 137 DYF403S1b  49  47 17 175 DYF403S1b  51  50 53 453 DYF403S1b  51  50 18 470 DYF403S1b  50  49 39 749 DYF403S1b  53  52 19 916 DYF403S1b  52  53 21 1090 DYF403S1b  50  49 Unknown 1288 DYF403S1b  52  51 25 1381 DYF403S1b  46.1  47.1 54 1447 DYF403S1b  49  50 Unknown 1479 DYF403S1b  48  49 23 1761 DYF403S1b  49  48 56 1947 DYF403S1b  46.1  47.1 54 1951 DYF404S1 (TTTC) ₁₅N₄₂(TTTC)₃ (TTTC) ₁₆N₄₂(TTTC)₃ 28 9 DYF404S1 (TTTC) ₁₅N₄₂(TTTC)₃ (TTTC) ₁₄N₄₂(TTTC)₃ 26 376 DYF404S1 (TTTC) ₁₆N₄₂(TTTC)₃ (TTTC) ₁₇N₄₂(TTTC)₃ 29 415 DYF404S1 (TTTC) ₁₆N₄₂(TTTC)₃ (TTTC) ₁₇N₄₂(TTTC)₃ 29 481 DYF404S1 (TTTC) ₁₆N₄₂(TTTC)₃ (TTTC) ₁₇N₄₂(TTTC)₃ 20 706 DYF404S1 (TTTC) ₁₅N₄₂(TTTC)₃ (TTTC) ₁₆N₄₂(TTTC)₃ 22 757 DYF404S1 (TTTC) ₁₅N₄₂(TTTC)₃ (TTTC) ₁₆N₄₂(TTTC)₃ 18 910 DYF404S1 (TTTC) ₁₆N₄₂(TTTC)₃ (TTTC) ₁₇N₄₂(TTTC)₃ 32 1007 DYF404S1 (TTTC) ₁₄N₄₂(TTTC)₃ (TTTC) ₁₅N₄₂(TTTC)₃ 23 1012 DYF404S1 (TTTC) ₁₅N₄₂(TTTC)₃ (TTTC) ₁₆N₄₂(TTTC)₃ 27 1049 DYF404S1 (TTTC) ₁₈N₄₂(TTTC)₃ (TTTC) ₁₇N₄₂(TTTC)₃ 31 1084 DYF404S1 (TTTC) ₁₄N₄₂(TTTC)₃ (TTTC) ₁₅N₄₂(TTTC)₃ 38 1114 DYF404S1 (TTTC) ₁₆N₄₂(TTTC)₃ (TTTC) ₁₅N₄₂(TTTC)₃ 21 1396 DYF404S1 (TTTC) ₁₆N₄₂(TTTC)₃ (TTTC) ₁₇N₄₂(TTTC)₃ 23 1546 DYF404S1 (TTTC) ₁₅N₄₂(TTTC)₃ (TTTC) ₁₄N₄₂(TTTC)₃ 40 1578 DYF404S1 (TTTC) ₁₇N₄₂(TTTC)₃ (TTTC) ₁₈N₄₂(TTTC)₃ 36 1655 DYF404S1 (TTTC) ₁₇N₄₂(TTTC)₃ (TTTC) ₁₆N₄₂(TTTC)₃ 26 1657 DYF404S1 (TTTC) ₁₆N₄₂(TTTC)₃ (TTTC) ₁₇N₄₂(TTTC)₃ 36 1687 DYF404S1 (TTTC) ₁₅N₄₂(TTTC)₃ (TTTC) ₁₄N₄₂(TTTC)₃ 19 1739 DYF404S1 (TTTC) ₁₈N₄₂(TTTC)₃ (TTTC) ₁₇N₄₂(TTTC)₃ 50 1881 DYF404S1 (TTTC) ₁₇N₄₂(TTTC)₃ (TTTC) ₁₈N₄₂(TTTC)₃ 60 1913 DYF405S1 (GGAA) ₁₁N₁₁₅(GGAA)₃(GAAA)₁(GGAA)₃ (GGAA) ₁₂N₁₁₅(GGAA)₃(GAAA)₁(GGAA)₃ 31 438 DYF405S1 (GGAA) ₁₄N₁₁₅(GGAA)₃(GAAA)₁(GGAA)₃ (GGAA) ₁₃N₁₁₅(GGAA)₃(GAAA)₁(GGAA)₃ 34 629 DYF406S1 (TATC) ₁₂ (TATC) ₁₁ 26 204 DYF406S1 (TATC) ₁₁ (TATC) ₁₀ 47 347 DYF406S1 (TATC) ₁₂ (TATC) ₁₃ 35 518 DYF406S1 (TATC) ₁₁ (TATC) ₁₀ 33 1011 DYF406S1 (TATC) ₁₂ (TATC) ₁₃ 41 1122 DYF406S1 (TATC) ₁₂ (TATC) ₁₃ Unknown 1263 DYF410S1 (AAAT) ₉ (AAAT) ₁₀ Unknown 1457 DYF410S1 (AAAT) ₉ (AAAT) ₁₀ 21 1667 DYS19 (TAGA)₃(TAGG)₁ (TAGA) ₁₃ (TAGA)₃(TAGG)₁ (TAGA) ₁₄ 46 21 DYS19 (TAGA)₃(TAGG)₁ (TAGA) ₁₁ (TAGA)₃(TAGG)₁ (TAGA) ₁₂ 43 472 DYS19 (TAGA)₃(TAGG)₁ (TAGA) ₁₄ (TAGA)₃(TAGG)₁ (TAGA) ₁₃ 24 726 DYS19 (TAGA)₃(TAGG)₁ (TAGA) ₁₄ (TAGA)₃(TAGG)₁ (TAGA) ₁₅ 31 927 DYS19 (TAGA)₃(TAGG)₁ (TAGA) ₁₂ (TAGA)₃(TAGG)₁ (TAGA) ₁₃ Unknown 1224 DYS19 (TAGA)₃(TAGG)₁ (TAGA) ₁₄ (TAGA)₃(TAGG)₁ (TAGA) ₁₃ 29 1257 DYS19 (TAGA)₃(TAGG)₁ (TAGA) ₁₄ (TAGA)₃(TAGG)₁ (TAGA) ₁₃ 24 1767 DYS385a (AAGG)₄N₁₄(AAAG)₃N₁₂(AAAG)₃N₂₉ (AAGG) ₆(GAAA)₁₃ (AAGG)₄N₁₄(AAAG)₃N₁₂(AAAG)₃N₂₉ (AAGG) ₅(GAAA)₁₃ 22 602 DYS385a (AAGG)₄N₁₄(AAAG)₃N₁₂(AAAG)₃N₂₉(AAGG)₆ (GAAA) ₁₃ (AAGG)₄N₁₄(AAAG)₃N₁₂(AAAG)₃N₂₉(AAGG)₆ (GAAA) ₁₄ 30 1000 DYS385a (AAGG)₄N₁₄(AAAG)₃N₁₂(AAAG)₃N₂₉(AAGG)₆ (GAAA) ₁₄ (AAGG)₄N₁₄(AAAG)₃N₁₂(AAAG)₃N₂₉(AAGG)₆ (GAAA) ₁₅ 60 1695 DYS385b (AAGG)₄N₁₄(AAAG)₃N₁₂(AAAG)₃N₂₉(AAGG)₆ (GAAA) ₁₅ (AAGG)₄N₁₄(AAAG)₃N₁₂(AAAG)₃N₂₉(AAGG)₆ (GAAA) ₁₆ 39 501 DYS385b (AAGG)₄N₁₄(AAAG)₃N₁₂(AAAG)₃N₂₉(AAGG)₆ (GAAA) ₁₅ (AAGG)₄N₁₄(AAAG)₃N₁₂(AAAG)₃N₂₉(AAGG)₆ (GAAA) ₁₆ 48 781 DYS385b (AAGG)₄N₁₄(AAAG)₃N₁₂(AAAG)₃N₂₉(AAGG)₆ (GAAA) ₁₄ (AAGG)₄N₁₄(AAAG)₃N₁₂(AAAG)₃N₂₉(AAGG)₆ (GAAA) ₁₅ 24 835 DYS385b (AAGG)₄N₁₄(AAAG)₃N₁₂(AAAG)₃N₂₉(AAGG)₆ (GAAA) ₁₄ (AAGG)₄N₁₄(AAAG)₃N₁₂(AAAG)₃N₂₉(AAGG)₆ (GAAA) ₁₅ 21 896 DYS385b (AAGG)₄N₁₄(AAAG)₃N₁₂(AAAG)₃N₂₉(AAGG)₆ (GAAA) ₁₄ (AAGG)₄N₁₄(AAAG)₃N₁₂(AAAG)₃N₂₉(AAGG)₆ (GAAA) ₁₅ 23 1080 DYS385b (AAGG)₄N₁₄(AAAG)₃N₁₂(AAAG)₃N₂₉(AAGG)₆ (GAAA) ₁₁ (AAGG)₄N₁₄(AAAG)₃N₁₂(AAAG)₃N₂₉(AAGG)₆ (GAAA) ₁₂ 52 1527 DYS389I (TCTG)₃ (TCTA) ₁₂ (TCTG)₃ (TCTA) ₁₁ 32 12 DYS389I (TCTG)₃ (TCTA) ₁₁ (TCTG)₃ (TCTA) ₁₀ 23 96 DYS389I (TCTG)₃ (TCTA) ₁₀ (TCTG)₃ (TCTA) ₁₁ 23 207 DYS389I (TCTG)₃ (TCTA) ₁₁ (TCTG)₃ (TCTA) ₁₀ 26 214 DYS389I (TCTG)₃ (TCTA) ₉ (TCTG)₃ (TCTA) ₁₀ 23 1119 DYS389I (TCTG)₃ (TCTA) ₁₀ (TCTG)₃ (TCTA) ₁₁ Unknown 1265 DYS389I (TCTG)₃ (TCTA) ₁₀ (TCTG)₃ (TCTA) ₉ 39 1700 DYS389I (TCTG)₃ (TCTA) ₁₀ (TCTG)₃ (TCTA) ₁₁ 46 1946 DYS389I (TCTG)₃ (TCTA) ₁₁ (TCTG)₃ (TCTA) ₁₀ 33 1966 DYS389II (TCTG)₅ (TCTA) ₁₂N₂₈(TCTG)₃(TCTA)₁₀ (TCTG)₅ (TCTA) ₁₁N₂₈(TCTG)₃(TCTA)₁₀ 32 401 DYS389II (TCTG)₅ (TCTA) ₁₄N₂₈(TCTG)₃(TCTA)₁₁ (TCTG)₅ (TCTA) ₁₃N₂₈(TCTG)₃(TCTA)₁₁ 36 519 DYS389II (TCTG)₅ (TCTA) ₁₃N₂₈(TCTG)₃(TCTA)₁₁ (TCTG)₅ (TCTA) ₁₂N₂₈(TCTG)₃(TCTA)₁₁ 21 721 DYS389II (TCTG)₅ (TCTA) ₁₂N₂₈(TCTG)₃(TCTA)₁₀ (TCTG)₅ (TCTA) ₁₃N₂₈(TCTG)₃(TCTA)₁₀ Unknown 1221 DYS389II (TCTG)₅ (TCTA) ₁₂N₂₈(TCTG)₃(TCTA)₉ (TCTG)₅ (TCTA) ₁₃N₂₈(TCTG)₃(TCTA)₉ 24 1312 DYS389II (TCTG)₅ (TCTA) ₁₃N₂₈(TCTG)₃(TCTA)₉ (TCTG)₅ (TCTA) ₁₂N₂₈(TCTG)₃(TCTA)₉ 54 1942 DYS390 (TCTG)₈ (TCTA) ₁₂(TCTG)₁(TCTG)₄ (TCTG)₈ (TCTA) ₁₁(TCTG)₁(TCTG)₄ 30 975 DYS390 (TCTG)₈ (TCTA) ₁₂(TCTG)₁(TCTG)₄ (TCTG)₈ (TCTA) ₁₁(TCTG)₁(TCTG)₄ 24 1148 DYS391 (TCTG)₃ (TCTA) ₁₁ (TCTG)₃ (TCTA) ₁₀ 20 240 DYS391 (TCTG)₃ (TCTA) ₁₀ (TCTG)₃ (TCTA) ₁₁ 22 689 DYS391 (TCTG)₃ (TCTA) ₁₁ (TCTG)₃ (TCTA) ₁₀ 31 881 DYS391 (TCTG)₃(TCTA) ₁₁ (TCTG)₃ (TCTA) ₁₂ 50 884 DYS391 (TCTG)₃ (TCTA) ₁₁ (TCTG)₃ (TCTA) ₁₂ 42 1411 DYS392 (TAT) ₁₃ (TAT) ₁₄ 60 1802 DYS393 (AGAT) ₁₄ (AGAT) ₁₃ 22 1028 DYS393 (AGAT) ₁₃ (AGAT) ₁₄ 42 1411 DYS393 (AGAT) ₁₄ (AGAT) ₁₅ 51 1852 DYS425 (TGT) ₁₃ (TGT) ₁₂ 31 1084 DYS425 (TGT) ₁₂ (TGT) ₁₃ 41 1476 DYS435 (TGGA) ₁₁ (TGGA) ₁₀ 19 916 DYS437 (TCTA) ₈(TCTG)₂(TCTA)₄ (TCTA) ₉(TCTG)₂(TCTA)₄ 32 1025 DYS437 (TCTA) ₉(TCTG)₂(TCTA)₄ (TCTA) ₁₀(TCTG)₂(TCTA)₄ 53 1869 DYS438 (TTTTC) ₁₂ (TTTTC) ₁₀, (TTTTC) ₁₂ 46 23 DYS439 (GATA)₃N₃₂ (GATA) ₁₀ (GATA)₃N₃₂ (GATA) ₁₁ 24 516 DYS439 (GATA)₃N₃₂ (GATA) ₁₃ (GATA)₃N₃₂ (GATA) ₁₄ 36 617 DYS439 (GATA)₃N₃₂ (GATA) ₁₃ (GATA)₃N₃₂ (GATA) ₁₂ 23 620 DYS439 (GATA)₃N₃₂ (GATA) ₁₃ (GATA)₃N₃₂ (GATA) ₁₂ 40 1204 DYS439 (GATA)₃N₃₂ (GATA) ₁₄ (GATA)₃N₃₂ (GATA) ₁₃ 37 1211 DYS439 (GATA)₃N₃₂ (GATA) ₁₃ (GATA)₃N₃₂ (GATA) ₁₂ 21 1463 DYS441 (TTCC) ₁₄ (TTCC) ₁₅ 38 589 DYS442 (GATA) ₁₃(GACA)₃ (GATA) ₁₂(GACA)₃ 32 213 DYS442 (GATA) ₁₃(GACA)₃ (GATA) ₁₂(GACA)₃ 26 354 DYS442 (GATA) ₁₃(GACA)₃ (GATA) ₁₂(GACA)₃ 45 409 DYS442 (GATA) ₁₅(GACA)₃ (GATA) ₁₄(GACA)₃ 28 425 DYS442 (GATA) ₁₆(GACA)₃ (GATA) ₁₅(GACA)₃ 30 533 DYS442 (GATA) ₁₄(GACA)₃ (GATA) ₁₃(GACA)₃ 26 775 DYS442 (GATA) ₁₅(GACA)₃ (GATA) ₁₄(GACA)₃ 27 953 DYS442 (GATA) ₁₄(GACA)₃ (GATA) ₁₅(GACA)₃ 30 1181 DYS442 (GATA) ₁₃(GACA)₃ (GATA) ₁₂(GACA)₃ 16 1238 DYS442 (GATA) ₁₂(GACA)₃ (GATA) ₁₁(GACA)₃ 39 1239 DYS442 (GATA) ₁₄(GACA)₃ (GATA) ₁₃(GACA)₃ Unknown 1245 DYS442 (GATA) ₁₂(GACA)₃ (GATA) ₁₃(GACA)₃ 28 1537 DYS442 (GATA) ₁₂(GACA)₃ (GATA) ₁₁(GACA)₃ 73 1884 DYS442 (GATA) ₁₃(GACA)₃ (GATA) ₁₂(GACA)₃ 51 1888 DYS443 (TTCC) ₁₅(CTT)₃ (TTCC) ₁₄(CTT)₃ 18 69 DYS443 (TTCC) ₁₄(CTT)₃ (TTCC) ₁₅(CTT)₃ 35 97 DYS443 (TTCC) ₁₄(CTT)₃ (TTCC) ₁₅(CTT)₃ 28 473 DYS444 (TAGA) ₁₂ (TAGA) ₁₁ 46 23 DYS444 (TAGA) ₁₃ (TAGA) ₁₂ 20 73 DYS444 (TAGA) ₁₃ (TAGA) ₁₂ 30 448 DYS444 (TAGA) ₁₄ (TAGA) ₁₅ 25 673 DYS444 (TAGA) ₁₅ (TAGA) ₁₄ 30 1067 DYS444 (TAGA) ₁₅ (TAGA) ₁₄ 22 1131 DYS444 (TAGA) ₁₅ (TAGA) ₁₄ 28 1294 DYS444 (TAGA) ₁₂ (TAGA) ₁₃ 33 1680 DYS444 (TAGA) ₁₃ (TAGA) ₁₂ 51 1813 DYS445 (TTTA) ₁₂ (TTTA) ₁₁ 57 464 DYS445 (TTTA) ₁₁ (TTTA) ₁₂ 22 886 DYS445 (TTTA) ₁₃ (TTTA) ₁₄ 21 1448 DYS446 (TCTCT) ₁₃ (TCTCT) ₁₄ 41 313 DYS446 (TCTCT) ₁₁ (TCTCT) ₁₀ 51 1442 DYS446 (TCTCT) ₁₂ (TCTCT) ₁₁ 55 1844 DYS446 (TCTCT) ₁₂ (TCTCT) ₁₃ 53 1893 DYS447 (TTATA)₆(TTATT)₁ (TTATA) ₈(TTATT)₁(TTATA)₇ (TTATA)₆(TTATT)₁ (TTATA) ₉(TTATT)₁(TTATA)₇ 33 690 DYS447 (TTATA)₇(TTATT)₁ (TTATA) ₁₀(TTATT)₁(TTATA)₇ (TTATA)₇(TTATT)₁ (TTATA) ₉(TTATT)₁(TTATA)₇ 47 1302 DYS447 (TTATA)₆(TTATT)₁(TTATA)₉(TTATT)₁ (TTATA) ₉ (TTATA)₆(TTATT)₁(TTATA)₉(TTATT)₁ (TTATA) ₈ 56 1677 DYS449 (TTCT)₁₅N₂₂(TTCT)₃N₁₂ (TTCT) ₁₆ (TTCT)₁₅N₂₂(TTCT)₃N₁₂ (TTCT) ₁₅ 29 78 DYS449 (TTCT) ₁₅N₂₂(TTCT)₃N₁₂(TTCT)₁₉ (TTCT) ₁₄N₂₂(TTCT)₃N₁₂(TTCT)₁₉ 27 170 DYS449 (TTCT) ₁₆N₂₂(TTCT)₃N₁₂(TTCT)₁₇ (TTCT) ₁₇N₂₂(TTCT)₃N₁₂(TTCT)₁₇ 23 251 DYS449 (TTCT) ₁₆N₂₂(TTCT)₃N₁₂(TTCT)₁₇ (TTCT) ₁₅N₂₂(TTCT)₃N₁₂(TTCT)₁₇ 38 449 DYS449 (TTCT)₁₅N₂₂(TTCT)₃N₁₂ (TTCT) ₁₈ (TTCT)₁₅N₂₂(TTCT)₃N₁₂ (TTCT) ₁₉ 39 492 DYS449 (TTCT)₁₇N₂₂(TTCT)₃N₁₂ (TTCT) ₁₃ (TTCT)₁₇N₂₂(TTCT)₃N₁₂ (TTCT)1 ₄ 35 531 DYS449 (TTCT)₁₄N₂₂(TTCT)₃N₁₂ (TTCT) ₁₄ (TTCT)₁₄N₂₂(TTCT)₃N₁₂ (TTCT) ₁₅ 34 568 DYS449 (TTCT)₁₆N₂₂(TTCT)₃N₁₂ (TTCT) ₁₆ (TTCT)₁₆N₂₂(TTCT)₃N₁₂ (TTCT) ₁₇ 21 786 DYS449 (TTCT)₁₆N₂₂(TTCT)₃N₁₂ (TTCT) ₁₇ (TTCT)₁₆N₂₂(TTCT)₃N₁₂ (TTCT) ₁₈ 25 840 DYS449 (TTCT) ₁₅N₂₂(TTCT)₃N₁₂(TTCT)₁₃ (TTCT) ₁₆N₂₂(TTCT)₃N₁₂(TTCT)₁₃ 22 894 DYS449 (TTCT)₁₅N₂₂(TTCT)₃N₁₂ (TTCT) ₁₈ (TTCT)₁₅N₂₂(TTCT)₃N₁₂ (TTCT) ₁₇ 37 904 DYS449 (TTCT)₁₅N₂₂(TTCT)₃N₁₂ (TTCT) ₁₇ (TTCT)₁₅N₂₂(TTCT)₃N₁₂ (TTCT) ₁₆ 33 966 DYS449 (TTCT) ₁₆N₂₂(TTCT)₃N₁₂(TTCT)₁₆ (TTCT) ₁₅N₂₂(TTCT)₃N₁₂(TTCT)₁₆ 24 1167 DYS449 (TTCT) ₁₅N₂₂(TTCT)₃N₁₂(TTCT)₁₄ (TTCT) ₁₆N₂₂(TTCT)₃N₁₂(TTCT)₁₄ 22 1349 DYS449 (TTCT) ₁₅N₂₂(TTCT)₃N₁₂(TTCT)₁₄ (TTCT) ₁₆N₂₂(TTCT)₃N₁₂(TTCT)₁₄ 45 1364 DYS449 (TTCT) ₁₈N₂₂(TTCT)₃N₁₂(TTCT)₁₆ (TTCT) ₁₉N₂₂(TTCT)₃N₁₂(TTCT)₁₆ 37 1418 DYS449 (TTCT)₁₄N₂₂(TTCT)₃N₁₂ (TTCT) ₁₄ (TTCT)₁₄N₂₂(TTCT)₃N₁₂ (TTCT) ₁₅ 21 1505 DYS449 (TTCT) ₁₅N₂₂(TTCT)₃N₁₂(TTCT)₁₅ (TTCT) ₁₄N₂₂(TTCT)₃N₁₂(TTCT)₁₅ 22 1526 DYS449 (TTCT)₁₄N₂₂(TTCT)₃N₁₂ (TTCT) ₁₅ (TTCT)₁₄N₂₂(TTCT)₃N₁₂ (TTCT) ₁₆ 54 1845 DYS450 (TTTTA) ₉N₁₂(TTTTA)₃ (TTTTA) ₈N₁₂(TTTTA)₃ 44 1619 DYS452 (TATAC) ₁₂[(CATAC)₁(TATAC)₁]₂N₂₀(TATAC)₃ (TATAC) ₁₃[(CATAC)₁(TATAC)₁]₂N₂₀(TATAC)₃ 17 967 (CATAC)₁(TATAC)₃ (CATAC)₁(TATAC)₃ DYS452 (TATAC) ₁₁[(CATAC)₁(TATAC)₁]₂N₂₀(TATAC)₃ (TATAC) ₁₂[(CATAC)₁(TATAC)₁]₂N₂₀(TATAC)₃ 26 971 (CATAC)₁(TATAC)₃ (CATAC)₁(TATAC)₃ DYS452 (TATAC) ₁₁[(CATAC)₁(TATAC)₁]₂N₂₀(TATAC)₃ (TATAC) ₁₀[(CATAC)₁(TATAC)₁]₂N₂₀(TATAC)₃ 33 1046 (CATAC)₁(TATAC)₃ (CATAC)₁(TATAC)₃ DYS452 (TATAC) ₁₀[(CATAC)₁(TATAC)₁]₂N₂₀(TATAC)₃ (TATAC) ₉[(CATAC)₁(TATAC)₁]₂N₂₀(TATAC)₃ 41 1453 (CATAC)₁(TATAC)₃ (CATAC)₁(TATAC)₃ DYS452 (TATAC)₈ [(CATAC) ₁ (TATAC) ₁ ] ₄N₂₀(TATAC)₃ (TATAC)₈ [(CATAC) ₁ (TATAC) ₁ ] ₃N₂₀(TATAC)₃ 55 1858 (CATAC)₁(TATAC)₃ (CATAC)₁(TATAC)₃ DYS456 (AGAT) ₁₅ (AGAT) ₁₆ 34 308 DYS456 (AGAT) ₁₆ (AGAT) ₁₇ 32 401 DYS456 (AGAT) ₁₅ (AGAT) ₁₆ 28 525 DYS456 (AGAT) ₁₆ (AGAT) ₁₇ 24 560 DYS456 (AGAT) ₁₅ (AGAT) ₁₆ 36 830 DYS456 (AGAT) ₁₇ (AGAT) ₁₆ 20 1037 DYS456 (AGAT) ₁₇ (AGAT) ₁₆ Unknown 1333 DYS456 (AGAT) ₁₆ (AGAT) ₁₇ 29 1790 DYS458 (GAAA) ₁₈ (GAAA) ₁₇ 25 307 DYS458 (GAAA) ₁₈ (GAAA) ₁₉ 41 313 DYS458 (GAAA) ₁₇ (GAAA) ₁₈ 28 466 DYS458 (GAAA) ₁₇ (GAAA) ₁₈ 27 734 DYS458 (GAAA) ₁₆ (GAAA) ₁₅ 24 771 DYS458 (GAAA) ₁₇ (GAAA) ₁₈ 29 826 DYS458 (GAAA) ₁₅ (GAAA) ₁₆ Unknown 1063 DYS458 (GAAA) ₁₆ (GAAA) ₁₅ 19 1132 DYS458 (GAAA) ₁₇ (GAAA) ₁₆ 34 1428 DYS458 (GAAA) ₁₆ (GAAA) ₁₇ 37 1454 DYS458 (GAAA) ₁₇ (GAAA) ₁₆ 19 1508 DYS458 (GAAA) ₁₇ (GAAA) ₁₆ Unknown 1613 DYS458 (GAAA) ₁₈ (GAAA) ₁₇ 64 1912 DYS458 (GAAA) ₁₈ (GAAA) ₁₉ 65 1920 DYS459 (ATTT) ₁₀ (ATTT) ₉ 29 246 DYS459 (ATTT) ₉ (ATTT) ₁₀ 26 573 DYS459 (ATTT) ₁₀ (ATTT) ₉ 43 928 DYS459 (ATTT) ₁₀ (ATTT) ₁₁ 27 1195 DYS460 (TAGA) ₁₃ (TAGA) ₁₂ 27 41 DYS460 (TAGA) ₉ (TAGA) ₁₀ 29 481 DYS460 (TAGA) ₁₁ (TAGA) ₁₀ 35 522 DYS460 (TAGA) ₁₂ (TAGA) ₁₁ 24 560 DYS460 (TAGA) ₁₁ (TAGA) ₁₀ 27 777 DYS460 (TAGA)₁₁ (TAGA)₁₀ 30 1062 DYS460 (TAGA)₁₂ (TAGA)₁₁ 33 1112 DYS460 (TAGA)₁₁ (TAGA)₁₀ 29 1601 DYS460 (TAGA)₁₀ (TAGA)₁₁ 21 1728 DYS460 (TAGA)₁₃ (TAGA)₁₂ 28 1734 DYS461 (TAGA)₁₁ (TAGA)₁₀ 23 1676 DYS462 (CATA)₁₁ (CATA)₁₀ 18 692 DYS462 (CATA)₁₃ (CATA)₁₂ 30 1425 DYS462 (CATA)₁₁ (CATA)₁₀ 39 1502 DYS462 (CATA)₁₁ (CATA)₁₂ 64 1912 DYS463 (AAAGG)₆(AAGGG)₁₅ (AAAGG)₆(AAGGG)₁₆ 36 327 DYS463 (AAAGG)₆(AAGGG)₁₃ (AAAGG)₆(AAGGG)₁₄ 54 1447 DYS464 (CCTT)₁₆N₄₆(CCTT)₃N₈(CCTT)₄ (CCTT)₁₇N₄₆(CCTT)₃N₈(CCTT)₄ 25 4 DYS464 (CCTT)₁₅N₄₆(CCTT)₃N₈(CCTT)₄ (CCTT)₁₄N₄₆(CCTT)₃N₈(CCTT)₄ 18 470 DYS464 (CCTT)₁₇N₄₆(CCTT)₃N₈(CCTT)₄ (CCTT)₁₆N₄₆(CCTT)₃N₈(CCTT)₄ 25 512 DYS464 (CCTT)₁₆N₄₆(CCTT)₃N₈(CCTT)₄ (CCTT)₁₉N₄₆(CCTT)₃N₈(CCTT)₄ 53 760 DYS464 (CCTT)₁₃N₄₆(CCTT)₃N₈(CCTT)₄ (CCTT)₁₄N₄₆(CCTT)₃N₈(CCTT)₄ 18 847 DYS464 (CCTT)₁₈N₄₆(CCTT)₃N₈(CCTT)₄ (CCTT)₁₆N₄₆(CCTT)₃N₈(CCTT)₄ 19 900 DYS464 (CCTT)₁₆N₄₆(CCTT)₃N₈(CCTT)₄ (CCTT)₁₅N₄₆(CCTT)₃N₈(CCTT)₄ 20 1185 DYS464 (CCTT)₁₇N₄₆(CCTT)₃N₈(CCTT)₄ (CCTT)₁₆N₄₆(CCTT)₃N₈(CCTT)₄ 31 1339 DYS464 (CCTT)₁₅N₄₆(CCTT)₃N₈(CCTT)₄ (CCTT)₁₆N₄₆(CCTT)₃N₈(CCTT)₄ 22 1526 DYS464 (CCTT)₁₈N₄₆(CCTT)₃N₈(CCTT)₄ (CCTT)₁₉N₄₆(CCTT)₃N₈(CCTT)₄ 43 1540 DYS464 (CCTT)₁₇N₄₆(CCTT)₃N₈(CCTT)₄ (CCTT)₁₆N₄₆(CCTT)₃N₈(CCTT)₄ 19 1784 DYS464 (CCTT)₁₈N₄₆(CCTT)₃N₈(CCTT)₄ (CCTT)₁₇N₄₆(CCTT)₃N₈(CCTT)₄ 56 1892 DYS468 (CTG)₄N₄₄(CCT)₃N₄₀(CTT)₃N₃₅(CCT)₄N₈ (CTG)₄N₄₄(CCT)3N₄₀(CTT)₃N₃₅(CCT)₄N₈ 29 1743 (CTC)₄(CTT)₈(ATTCAT)₈ (CTC)₄(CTT)₉(ATTCAT)₈ DYS468 (CTG)₄N₄₄(CCT)₃N₄₀(CTT)₃N₃₅(CCT)₄N₈ (CTG)₄N₄₄(CCT)₃N₄₀(CTT)₃N₃₅(CCT)₄N₈ 60 1802 (CTC)₄(CTT)₉(ATTCAT)₉ (CTC)₄(CTT)₉(ATTCAT)₈ DYS469 (CTT)₃N₃₉(CTT)₄(GTT)₁(CTT)₂₀T(CTT)₃N₁₇(CTT)₅N₃₇(CTT)₃ (CTT)₃N₃₉(CTT)₄(GTT)₁(CTT)₂₁T(CTT)₃N₁₇(CTT)₅N₃₇ 24 107 N₁₂(CTT)₄N₁₂(CTT)₃N₁₂(CTT)₅(CCT)₄N₉(CTT)₃(CCT)₃ (CTT)₃N₁₂(CTT)₄N₁₂(CTT)₃N₁₂(CTT)₅(CCT)₄N₉(CTT)₃(CCT)₃ DYS469 (CTT)₃N₃₉(CTT)₄(GTT)₁(CTT)₁₅T(CTT)₃N₁₇(CTT)₅N₃₇(CTT)₃ (CTT)₃N₃₉(CTT)₄(GTT)₁(CTT)₁₆T(CTT)₃N₁₇(CTT)₅N₃₇(CTT)₃ 21 769 N₁₂(CTT)₄N₁₂(CTT)₃N₁₂(CTT)₅(CCT)₄N₉(CTT)₃(CCT)₃ N₁₂(CTT)₄N₁₂(CTT)₃N₁₂(CTT)₅(CCT)₄N₉(CTT)₃(CCT)₃ DYS469 (CTT)₃N₃₉(CTT)₄(GTT)₁(CTT)₁₅T(CTT)₃N₁₇(CTT)₅N₃₇(CTT)₃ (CTT)₃N₃₉(CTT)₄(GTT)₁(CTT)₁₆T(CTT)₃N₁₇(CTT)₅N₃₇(CTT)₃ 29 1491 N₁₂(CTT)₄N₁₂(CTT)₃N₁₂(CTT)₅(CCT)₄N₉(CTT)₃(CCT)₃ N₁₂(CTT)₄N₁₂(CTT)₃N₁₂(CTT)₅(CCT)₄N₉(CTT)₃(CCT)₃ DYS469 (CTT)₃N₃₉(CTT)₄(GTT)₁(CTT)₁₆T(CTT)₃N₁₇(CTT)₅N₃7(CTT)₃ (CTT)₃N₃₉(CTT)₄(GTT)₁(CTT)₁₅T(CTT)₃N₁₇(CTT)₅N₃₇(CTT)₃ 29 1693 N₁₂(CTT)₄N₁₂(CTT)₃N₁₂(CTT)₅(CCT)₄N₉(CTT)₃(CCT)₃ N₁₂(CTT)₄N₁₂(CTT)₃N₁₂(CTT)₅(CCT)₄N₉(CTT)₃(CCT)₃ DYS476 (TGA)₁₁ (TGA)₁₂ 59 1867 DYS481 (CTT)₂₈ (CTT)₂₉ 30 99 DYS481 (CTT)₂₂ (CTT)₂₃ 32 655 DYS481 (CTT)₃₀ (CTT)₂₉ 24 778 DYS481 (CTT)₃₂ (CTT)₃₁ 17 845 DYS481 (CTT)₃₁ (CTT)₃₀ 24 1370 DYS481 (CTT)₂₃ (CTT)₂₁ 42 1411 DYS481 (CTT)₂₅ (CTT)₂₄ 36 1672 DYS481 (CTT)₂₂ (CTT)₂₃ 54 1895 DYS484 (AAT)₁₃N₁₂(AAT)₃(TAT)₃ (AAT)₁₁N₁₂(AAT)₃(TAT)₃ 22 45 DYS484 (AAT)₁₃N₁₂(AAT)₃(TAT)₃ (AAT)₁₄N₁₂(AAT)₃(TAT)₃ 35 875 DYS484 (AAT)₁₂N₁₂(AAT)₃(TAT)₃ (AAT)₁₃N₁₂(AAT)₃(TAT)₃ 25 1213 DYS484 (AAT)₁₂N₁₂(AAT)₃(TAT)₃ (AAT)₁₀N₁₂(AAT)₃(TAT)₃ 26 1653 DYS487 (AAT)₁₃ (AAT)₁₄ 21 172 DYS487 (AAT)₁₄ (AAT)₁₃ 28 1410 DYS495 (AAT)₁₅ (AAT)₁₆ 26 775 DYS495 (AAT)₁₅ (AAT)₁₆ 30 1274 DYS495 (AAT)₁₇ (AAT)₁₆ 31 1596 DYS497 (TTA)₁₅ (TTA)₁₄ 25 58 DYS497 (TTA)₁₅ (TTA)₁₆ 40 305 DYS504 (CCTT)₁₇N₇(CCCT)₃ (CCTT)₁₆N₇(CCCT)₃ 25 275 DYS504 (CCTT)₁₉N₇(CCCT)₃ (CCTT)₁₈N₇(CCCT)₃ Unknown 1223 DYS504 (CCTT)₁₇N₇(CCCT)₃ (CCTT)₁₈N₇(CCCT)₃ 39 1502 DYS504 (CCTT)₁₈N₇(CCCT)₃ (CCTT)₁₇N₇(CCCT)₃ 30 1796 DYS504 (CCTT)₁₈N₇(CCCT)₃ (CCTT)₁₇N₇(CCCT)₃ 54 1895 DYS505 (TCCT)₁₃ (TCCT)₁₂ 64 951 DYS505 (TCCT)₁₂ (TCCT)₁₃ 25 1070 DYS508 (TATC)₁₀ (TATC)₁₁ 32 1369 DYS508 (TATC)₁₁ (TATC)₁₂ 21 1635 DYS508 (TATC)₁₁ (TATC)₁₀ 20 1862 DYS508 (TATC)₁₄ (TATC)₁₃ 67 1954 DYS509 (AAAT)₁₀(AATAA)₁(AAAT)₃ (AAAT)₉(AATAA)₁(AAAT)₃ 18 680 DYS510 (GATA)₃N₁₂(GATA)₁₂N₁₃(GGAT)₄N₉(GATA)₃ (GATA)₃N₁₂(GATA)₁₃N₁₃(GGAT)₄N₉(GATA)₃ 24 17 DYS510 (GATA)₃N₁₂(GATA)₁₂N₁₃(GGAT)₄N₉(GATA)₃ (GATA)₃N₁₂(GATA)₁₁N₁₃(GGAT)₄N₉(GATA)₃ 64 166 DYS510 (GATA)₃N₁₂(GATA)₁₂N₁₃(GGAT)₄N₉(GATA)₃ (GATA)₃N₁₂(GATA)₁₁N₁₃(GGAT)₄N₉(GATA)₃ 25 185 DYS510 (GATA)₃N₁₂(GATA)₁₅N₁₃(GGAT)₄N₉(GATA)₃ (GATA)₃N₁₂(GATA)₁₄N₁₃(GGAT)₄N₉(GATA)₃ 19 761 DYS510 (GATA)₃N₁₂(GATA)₁₁N₁₃(GGAT)₄N₉(GATA)₃ (GATA)3N₁₂(GATA)₁₀N₁₃(GGAT)₄N₉(GATA)₃ 19 916 DYS510 (GATA)₃N₁₂(GATA)₁₄N₁₃(GGAT)₄N₉(GATA)₃ (GATA)₃N₁₂(GATA)₁₅N₁₃(GGAT)₄N₉(GATA)₃ 43 928 DYS510 (GATA)₃N₁₂(GATA)₁₂N₁₃(GGAT)₄N₉(GATA)₃ (GATA)₃N₁₂(GATA)₁₁N₁₃(GGAT)₄N₉(GATA)₃ 33 1112 DYS510 (GATA)₃N₁₂(GATA)₁₃N₁₃(GGAT)₄N₉(GATA)₃ (GATA)₃N₁₂(GATA)₁₂N₁₃(GGAT)₄N₉(GATA)₃ 34 1118 DYS510 (GATA)₃N₁₂(GATA)₁₄N₁₃(GGAT)₄N₉(GATA)₃ (GATA)₃N₁₂(GATA)₁₅N₁₃(GGAT)₄N₉(GATA)₃ 45 1364 DYS510 (GATA)₃N₁₂(GATA)₁₂N₁₃(GGAT)₄N₉(GATA)₃ (GATA)₃N₁₂(GATA)₁₃N₁₃(GGAT)₄N₉(GATA)₃ 28 1758 DYS511 (GATA)₁₃ (GATA)₁₂ 22 418 DYS511 (GATA)₁₁ (GATA)₁₂ 52 1804 DYS513 (TCTA)₄(TCCA)₁(TATC)₃(CGTA)₁(TCTA)₁₂ (TCTA)₄(TCCA)₁(TATC)₃(CGTA)₁(TCTA)₁₃ 33 29 DYS513 (TCTA)₄(TCCA)₁(TATC)₃(CGTA)₁(TCTA)₁₄ (TCTA)₄(TCCA)₁(TATC)₃(CGTA)₁(TCTA)₁₃ 23 134 DYS513 (TCTA)₄(TCCA)₁(TATC)₃(CGTA)₁(TCTA)₁₃ (TCTA)₄(TCCA)₁(TATC)₃(CGTA)₁(TCTA)₁₂ 33 187 DYS513 (TCTA)₄(TCCA)₁(TATC)₃(CGTA)₁(TCTA)₁₃ (TCTA)₄(TCCA)₁(TATC)₃(CGTA)₁(TCTA)₁₄ 30 1181 DYS513 (TCTA)₄(TCCA)₁(TATC)₃(CGTA)₁(TCTA)₁₃ (TCTA)₄(TCCA)₁(TATC)₃(CGTA)₁(TCTA)₁₄ 21 1216 DYS513 (TCTA)₄(TCCA)₁(TATC)₃(CGTA)₁(TCTA)₁₃ (TCTA)₄(TCCA)₁(TATC)₃(CGTA)₁(TCTA)₁₄ Unknown 1308 DYS513 (TCTA)₄(TCCA)₁(TATC)₃(CGTA)₁(TCTA)₁₂ (TCTA)₄(TCCA)₁(TATC)₃(CGTA)₁(TCTA)₁₁ 22 1323 DYS513 (TCTA)₄(TCCA)₁(TATC)₃(CGTA)₁(TCTA)₁₂ (TCTA)₄(TCCA)₁(TATC)₃(CGTA)₁(TCTA)₁₃ 36 1421 DYS513 (TCTA)₄(TCCA)₁(TATC)₃(CGTA)₁(TCTA)₁₃ (TCTA)₄(TCCA)₁(TATC)₃(CGTA)₁(TCTA)₁₂ 36 1672 DYS513 (TCTA)₄(TCCA)₁(TATC)₃(CGTA)₁(TCTA)₁₁ (TCTA)₄(TCCA)₁(TATC)₃(CGTA)₁(TCTA)₁₂ 60 1695 DYS516 (TTCT)₄N₃₀(TTCT)₁₆ (TTCT)₄N₃₀(TTCT)₁₅ 28 106 DYS516 (TTCT)₄N₃₀(TTCT)₁₄ (TTCT)₄N₃₀(TTCT)₁₃ 37 904 DYS516 (TTCT)₄N₃₀(TTCT)₁₂ (TTCT)₄N₃₀(TTCT)₁₃ 44 973 DYS516 (TTCT)₄N₃₀(TTCT)₁₅ (TTCT)₄N₃₀(TTCT)₁₆ 34 1030 DYS516 (TTCT)₄N₃₀(TTCT)₁₃ (TTCT)₄N₃₀(TTCT)₁₄ Unknown 1241 DYS516 (TTCT)₄N₃₀(TTCT)₁₂ (TTCT)₄N₃₀(TTCT)₁₃ 38 1524 DYS516 (TTCT)₄N₃₀(TTCT)₁₄ (TTCT)₄N₃₀(TTCT)₁₅ 42 1628 DYS516 (TTCT)₄N₃₀(TTCT)₁₅ (TTCT)₄N₃₀(TTCT)₁₆ 22 1778 DYS516 (TTCT)₄N₃₀(TTCT)₁₅ (TTCT)₄N₃₀(TTCT)₁₆ 24 1782 DYS516 (TTCT)₄N₃₀(TTCT)₁₂ (TTCT)₄N₃₀(TTCT)₁₁ 53 1869 DYS516 (TTCT)₄N₃₀(TTCT)₁₇ (TTCT)₄N₃₀(TTCT)₁₅ 50 1881 DYS517 (AAAG)₁₆N₈(AAAG)₃ (AAAG)₁₅N₈(AAAG)₃ 26 802 DYS517 (AAAG)₁₄N₈(AAAG)₃ (AAAG)₁₅N₈(AAAG)₃ 30 1796 DYS517 (AAAG)₁₆N₈(AAAG)₃ (AAAG)₁₅N₈(AAAG)₃ 63 1807 DYS517 (AAAG)₁₄N₈(AAAG)₃ (AAAG)₁₅N₈(AAAG)₃ 54 1860 DYS517 (AAAG)₁₄N₈(AAAG)₃ (AAAG)₁₅N₈(AAAG)₃ 53 1869 DYS518 (AAAG)₃(GAAG)₁(AAAG)₁₆(GGAG)₁(AAAG)₄ (AAAG)₃(GAAG)₁(AAAG)₁₅(GGAG)₁(AAAG)₄ 33 29 N₆(AAAG)₁₇N₂₇(AAGG)₄ N₆(AAAG)₁₇N₂₇(AAGG)₄ DYS518 (AAAG)₃(GAAG)₁(AAAG)₁₄(GGAG)₁(AAAG)₄ (AAAG)₃(GAAG)₁(AAAG)₁₄(GGAG)₁(AAAG)₄ 32 56 N₆(AAAG)₁₄N₂₇(AAGG)₄ N₆(AAAG)₁₅N₂₇(AAGG)₄ DYS518 (AAAG)₃(GAAG)₁(AAAG)₁₇(GGAG)₁(AAAG)₄ (AAAG)₃(GAAG)₁(AAAG)₁₆(GGAG)₁(AAAG)₄ 48 74 N₆(AAAG)₁₂N₂₇(AAGG)₄ N₆(AAAG)₁₂N₂₇(AAGG)₄ DYS518 (AAAG)₃(GAAG)₁(AAAG)₁₅(GGAG)₁(AAAG)₄ (AAAG)₃(GAAG)₁(AAAG)₁₄(GGAG)₁(AAAG)₄ 30 87 N₆(AAAG)₁₅N₂₇(AAGG)₄ N₆(AAAG)₁₅N₂₇(AAGG)₄ DYS518 (AAAG)₃(GAAG)₁(AAAG)₁₈(GGAG)₁(AAAG)₄ (AAAG)₃(GAAG)₁(AAAG)₁₇(GGAG)₁(AAAG)₄ 34 88 N₆(AAAG)₁₆N₂₇(AAGG)₄ N₆(AAAG)₁₆N₂₇(AAGG)₄ DYS518 (AAAG)₃(GAAG)₁(AAAG)₁₇(GGAG)₁(AAAG)₄ (AAAG)₃(GAAG)₁(AAAG)₁₆(GGAG)₁(AAAG)₄ 29 89 N₆(AAAG)₁₃N₂₇(AAGG)₄ N₆(AAAG)₁₃N₂₇(AAGG)₄ DYS518 (AAAG)₃(GAAG)₁(AAAG)₁₉(GGAG)₁(AAAG)₄ (AAAG)₃(GAAG)₁(AAAG)₁₈(GGAG)₁(AAAG)₄ 50 270 N₆(AAAG)₁₇N₂₇(AAGG)₄ N₆(AAAG)₁₇N₂₇(AAGG)₄ DYS518 (AAAG)₃(GAAG)₁(AAAG)₁₈(GGAG)₁(AAAG)₄ (AAAG)₃(GAAG)₁(AAAG)₁₉(GGAG)₁(AAAG)₄ 25 426 N₆(AAAG)₁₅N₂₇(AAGG)₄ N₆(AAAG)₁₅N₂₇(AAGG)₄ DYS518 (AAAG)₃(GAAG)₁ (AAAG) ₂₂(GGAG)₁(AAAG)₄ (AAAG)₃(GAAG)₁ (AAAG) ₂₁(GGAG)₁(AAAG)₄ 26 433 N₆(AAAG)₁₃N₂₇(AAGG)₄ N₆(AAAG)₁₃N₂₇(AAGG)₄ DYS518 (AAAG)₃(GAAG)₁(AAAG)₁₅(GGAG)₁(AAAG)₄ (AAAG)₃(GAAG)₁(AAAG)₁₅(GGAG)₁(AAAG)₄ 28 525 N₆ (AAAG) ₁₂N₂₇(AAGG)₄ N₆ (AAAG) ₁₁N₂₇(AAGG)₄ DYS518 (AAAG)₃(GAAG)₁(AAAG)₁₅(GGAG)₁(AAAG)₄ (AAAG)₃(GAAG)₁(AAAG)₁₅(GGAG)₁(AAAG)₄ 24 571 N₆ (AAAG) ₁₇N₂₇(AAGG)₄ N₆ (AAAG) ₁₆N₂₇(AAGG)₄ DYS518 (AAAG)₃(GAAG)₁ (AAAG) ₁₈(GGAG)₁(AAAG)₄ (AAAG)₃(GAAG)₁ (AAAG) ₁₇(GGAG)₁(AAAG)₄ 21 593 N₆(AAAG)₁₄N₂₇(AAGG)₄ N₆(AAAG)₁₄N₂₇(AAGG)₄ DYS518 (AAAG)₃(GAAG)₁ (AAAG) ₁₆(GGAG)₁(AAAG)₄N₆(AAAG)₁N₂₇ (AAAG)₃(GAAG)₁ (AAAG) ₁₅(GGAG)₁(AAAG)₄ 23 687 (AAGG)₄ N₆(AAAG)₁₇N₂₇(AAGG)₄ DYS518 (AAAG)₃(GAAG)₁(AAAG)₁₆(GGAG)₁(AAAG)₄ (AAAG)₃(GAAG)₁(AAAG)₁₆(GGAG)₁(AAAG)₄ 20 703 N₆ (AAAG) ₁₄N₂₇(AAGG)₄ N₆ (AAAG) ₁₅N₂₇(AAGG)₄ DYS518 (AAAG)₃(GAAG)₁ (AAAG) ₁₇(GGAG)₁(AAAG)₄ (AAAG)₃(GAAG)₁ (AAAG) ₁₆(GGAG)₁(AAAG)₄ 20 741 N₆(AAAG)₁₅N₂₇(AAGG)₄ N₆(AAAG)₁₅N₂₇(AAGG)₄ DYS518 (AAAG)₃(GAAG)₁(AAAG)₁₅(GGAG)₁(AAAG)₄ (AAAG)₃(GAAG)₁(AAAG)₁₅(GGAG)₁(AAAG)₄ 22 747 N₆ (AAAG) ₁₆N₂₇(AAGG)₄ N₆ (AAAG) ₁₇N₂₇(AAGG)₄ DYS518 (AAAG)₃(GAAG)₁ (AAAG) ₁₅(GGAG)₁(AAAG)₄ (AAAG)₃(GAAG)₁ (AAAG) ₁₆(GGAG)₁(AAAG)₄ 15 763 N₆(AAAG)₁₆N₂₇(AAGG)₄ N₆(AAAG)₁₆N₂₇(AAGG)₄ DYS518 (AAAG)₃(GAAG)₁ (AAAG) ₁₇(GGAG)₁(AAAG)₄ (AAAG)₃(GAAG)₁ (AAAG) ₁₆(GGAG)₁(AAAG)₄ 22 817 N₆(AAAG)₁₄N₂₇(AAGG)₄ N₆(AAAG)₁₆N₂₇(AAGG)₄ DYS518 (AAAG)₃(GAAG)₁(AAAG)₁₆(GGAG)₁(AAAG)₄ (AAAG)₃(GAAG)₁(AAAG)₁₆(GGAG)₁(AAAG)₄ 23 888 N₆ (AAAG) ₁₈N₂₇(AAGG)₄ N₆ (AAAG) ₁₇N₂₇(AAGG)₄ DYS518 (AAAG)₃(GAAG)₁ (AAAG) ₁₅(GGAG)₁(AAAG)₄ (AAAG)₃(GAAG)₁ (AAAG) ₁₄(GGAG)₁(AAAG)₄ 19 916 N₆(AAAG)₁₆N₂₇(AAGG)₄ N₆(AAAG)₁₆N₂₇(AAGG)₄ DYS518 (AAAG)₃(GAAG)₁(AAAG)₁₇(GGAG)₁(AAAG)₄ (AAAG)₃(GAAG)₁(AAAG)₁₇(GGAG)₁(AAAG)₄ 56 1043 N₆ (AAAG) ₁₆N₂₇(AAGG)₄ N₆ (AAAG) ₁₅N₂₇(AAGG)₄ DYS518 (AAAG)₃(GAAG)₁(AAAG)₁₇(GGAG)₁(AAAG)₄ (AAAG)₃(GAAG)₁(AAAG)₁₇(GGAG)₁(AAAG)₄ 37 1107 N₆ (AAAG) ₁₇N₂₇(AAGG)₄ N₆ (AAAG) ₁₆N₂₇(AAGG)₄ DYS518 (AAAG)₃(GAAG)₁(AAAG)₁₈(GGAG)₁(AAAG)₄ (AAAG)₃(GAAG)₁(AAAG)₁₈(GGAG)₁(AAAG)₄ 19 1115 N₆ (AAAG) ₁₇N₂₇(AAGG)₄ N₆ (AAAG) ₁₈N₂₇(AAGG)₄ DYS518 (AAAG)₃(GAAG)₁(AAAG)₁₇(GGAG)₁(AAAG)₄ (AAAG)₃(GAAG)₁(AAAG)₁₇(GGAG)₁(AAAG)₄ 21 1273 N₆ (AAAG) ₁₇N₂₇(AAGG)₄ N₆ (AAAG) ₁₆N₂₇(AAGG)₄ DYS518 (AAAG)₃(GAAG)₁ (AAAG) ₁₅(GGAG)₁(AAAG)₄ (AAAG)₃(GAAG)₁ (AAAG) ₁₆(GGAG)₁(AAAG)₄ 45 1364 N₆(AAAG)₁₃N₂₇(AAGG)₄ N₆(AAAG)₁₃N₂₇(AAGG)₄ DYS518 (AAAG)₃(GAAG)₁ (AAAG) ₁₆(GGAG)₁(AAAG)₄ (AAAG)₃(GAAG)₁ (AAAG) ₁₅(GGAG)₁(AAAG)₄ 42 1411 N₆ (AAAG) ₁₇N₂₇(AAGG)₄ N₆ (AAAG) ₁₅N₂₇(AAGG)₄ DYS518 (AAAG)₃(GAAG)₁(AAAG)₁₆(GGAG)₁(AAAG)₄ (AAAG)₃(GAAG)₁(AAAG)₁₆(GGAG)₁(AAAG)₄ 32 1545 N₆ (AAAG) ₁₈N₂₇(AAGG)₄ N₆ (AAAG) ₁₉N₂₇(AAGG)₄ DYS518 (AAAG)₃(GAAG)₁ (AAAG) ₁₆(GGAG)₁(AAAG)₄ (AAAG)₃(GAAG)₁ (AAAG) ₁₅(GGAG)₁(AAAG)₄ 29 1790 N₆(AAAG)₁₅N₂₇(AAGG)₄ N₆(AAAG)₁₅N₂₇(AAGG)₄ DYS520 (GATA) ₁₂(CATA)₁₁ (GATA) ₁₁(CATA)₁₁ 32 56 DYS520 (GATA) ₁₂(CATA)₁₁ (GATA) ₁₁(CATA)₁₁ 34 88 DYS520 (GATA)₁₂ (CATA) ₁₀ (GATA)₁₂ (CATA) ₁₁ 31 141 DYS520 (GATA) ₁₁(CATA)₁₁ (GATA) ₁₂(CATA)₁₁ 31 434 DYS521 (CTTT)₅(TCTT)₃(TTTT)₁(CTTT)₅T(CTTT) ₁₃ (CTTT)₅(TCTT)₃(TTTT)₁(CTTT)₅T(CTTT) ₁₂ 25 133 DYS522 (ATAG) ₁₀ (ATAG) ₁₁ 22 1088 DYS525 (AGAT) ₁₁ (AGAT) ₁₀ 24 571 DYS526a (CCTT) ₁₆ (CCTT) ₁₅ 64 166 DYS526a (CCTT) ₁₃ (CCTT) ₁₄ 53 453 DYS526a (CCTT) ₁₄ (CCTT) ₁₃ 31 1315 DYS526a (CCTT) ₁₁ (CCTT) ₁₂ 31 1652 DYS526b (CCCT)₃N₂₀ (CTTT) ₁₄(CCTT)₉N₁₁₃(CCTT)₁₁ (CCCT)₃N₂₀ (CTTT) ₁₃(CCTT)₉N₁₁₃(CCTT)₁₁ 24 17 DYS526b (CCCT)₃N₂₀ (CTTT) ₁₆(CCTT)₉N₁₁₃(CCTT)₁₄ (CCCT)₃N₂₀ (CTTT) ₁₅(CCTT)₉N₁₁₃(CCTT)₁₄ 50 42 DYS526b (CCCT)₃N₂₀ (CTTT) ₁₇(CCTT)₉N₁₁₃(CCTT)₁₄ (CCCT)₃N₂₀ (CTTT) ₁₆(CCTT)₉N₁₁₃(CCTT)₁₄ 34 88 DYS526b (CCCT)₃N₂₀ (CTTT) ₁₆(CCTT)₉N₁₁₃(CCTT)₁₂ (CCCT)₃N₂₀ (CTTT) ₁₅(CCTT)₉N₁₁₃(CCTT)₁₂ 25 185 DYS526b (CCCT)₃N₂₀ (CTTT) ₁₇(CCTT)₉N₁₁₃(CCTT)₁₄ (CCCT)₃N₂₀ (CTTT) ₁₆(CCTT)₉N₁₁₃(CCTT)₁₄ 41 298 DYS526b (CCCT)₃N₂₀ (CTTT) ₁₆(CCTT)₉N₁₁₃(CCTT)₁₄ (CCCT)₃N₂₀ (CTTT) ₁₅(CCTT)₉N₁₁₃(CCTT)₁₄ 41 386 DYS526b (CCCT)₃N₂₀ (CTTT) ₁₁(CCTT)₉N₁₁₃(CCTT)₁₄ (CCCT)₃N₂₀ (CTTT) ₁₂(CCTT)₉N₁₁₃(CCTT)₁₄ 31 505 DYS526b (CCCT)₃N₂₀ (CTTT) ₁₆(CCTT)₉N₁₁₃(CCTT)₁₀ (CCCT)₃N₂₀ (CTTT) ₁₇(CCTT)₉N₁₁₃(CCTT)₁₀ 32 523 DYS526b (CCCT)₃N₂₀ (CTTT) ₁₇(CCTT)₉N₁₁₃(CCTT)₁₀ (CCCT)₃N₂₀ (CTTT) ₁₆(CCTT)₉N₁₁₃(CCTT)₁₀ 39 654 DYS526b (CCCT)₃N₂₀ (CTTT) ₁₆(CCTT)₉N₁₁₃(CCTT)₁₄ (CCCT)₃N₂₀ (CTTT) ₁₇(CCTT)₉N₁₁₃(CCTT)₁₄ 25 918 DYS526b (CCCT)₃N₂₀(CTTT)₁₅ (CCTT) ₉N₁₁₃(CCTT)₁₄ (CCCT)₃N₂₀(CTTT)₁₅ (CCTT) ₈N₁₁₃(CCTT)₁₄ 36 983 DYS526b (CCCT)₃N₂₀ (CTTT) ₁₅(CCTT)₉N₁₁₃(CCTT)₁₄ (CCCT)₃N₂₀ (CTTT) ₁₆(CCTT)₉N₁₁₃(CCTT)₁₄ 37 1107 DYS526b (CCCT)₃N₂₀ (CTTT) ₁₄(CCTT)₉N₁₁₃(CCTT)₁₄ (CCCT)₃N₂₀ (CTTT) ₁₅(CCTT)₉N₁₁₃(CCTT)₁₄ 41 1122 DYS526b (CCCT)₃N₂₀ (CTTT) ₁₅(CCTT)₉N₁₁₃(CCTT)₁₄ (CCCT)₃N₂₀ (CTTT) ₁₄(CCTT)₉N₁₁₃(CCTT)₁₄ 22 1161 DYS526b (CCCT)₃N₂₀ (CTTT) ₁₃(CCTT)₉N₁₁₃(CCTT)₁₄ (CCCT)₃N₂₀ (CTTT) ₁₄(CCTT)₉N₁₁₃(CCTT)₁₄ 45 1171 DYS526b (CCCT)₃N₂₀ (CTTT) ₁₆(CCTT)₉N₁₁₃(CCTT)₁₄ (CCCT)₃N₂₀ (CTTT) ₁₅(CCTT)₉N₁₁₃(CCTT)₁₄ 48 1250 DYS526b (CCCT)₃N₂₀ (CTTT) ₁₃(CCTT)₉N₁₁₃(CCTT)₁₂ (CCCT)₃N₂₀ (CTTT) ₁₄(CCTT)₉N₁₁₃(CCTT)₁₂ 54 1447 DYS526b (CCCT)₃N₂₀ (CTTT) ₁₃(CCTT)₉N₁₁₃(CCTT)₁₃ (CCCT)₃N₂₀ (CTTT) ₁₂(CCTT)₉N₁₁₃(CCTT)₁₃ 21 1555 DYS526b (CCCT)₃N₂₀ (CTTT) ₁₄(CCTT)₉N₁₁₃(CCTT)₁₃ (CCCT)₃N₂₀ (CTTT) ₁₅(CCTT)₉N₁₁₃(CCTT)₁₃ 29 1662 DYS526b (CCCT)₃N₂₀ (CTTT) ₁₅(CCTT)₉N₁₁₃(CCTT)₁₄ (CCCT)₃N₂₀ (CTTT) ₁₆(CCTT)₉N₁₁₃(CCTT)₁₄ 50 1881 DYS531 (AAAT) ₁₁ (AAAT) ₉ 22 747 DYS532 (TCCC)₃N₅(TTCC)₅N₉(TTCT)₃(TTCC)₁ (TTCT) ₁₂N₁₇(TTCT)₃ (TCCC)₃N₅(TTCC)₅N₉(TTCT)₃(TTCC)₁ (TTCT) ₁₃N₁₇(TTCT)₃ 26 759 N₁₃(TTCC)₄N₇₀(TTCT)₃N₆(TTCT)₃ N₁₃(TTCC)₄N₇₀(TTCT)₃N₆(TTCT)₃ DYS532 (TCCC)₃N₅(TTCC)₅N₉(TTCT)₃(TTCC)₁ (TTCT) ₁₂N₁₇(TTCT)₃ (TCCC)₃N₅(TTCC)₅N₉(TTCT)₃(TTCC)₁ (TTCT) ₁₁N₁₇(TTCT)₃ 30 1101 N₁₃(TTCC)₄N₇₀(TTCT)₃N₆(TTCT)₃ N₁₃(TTCC)₄N₇₀(TTCT)₃N₆(TTCT)₃ DYS532 (TCCC)₃N₅(TTCC)₅N₉(TTCT)₃(TTCC)₁ (TTCT) ₁₂N₁₇(TTCT)₃ (TCCC)₃N₅(TTCC)₅N₉(TTCT)₃(TTCC)₁ (TTCT) ₁₃N₁₇(TTCT)₃ 29 1255 N₁₃(TTCC)₄N₇₀(TTCT)₃N₆(TTCT)₃ N₁₃(TTCC)₄N₇₀(TTCT)₃N₆(TTCT)₃ DYS532 (TCCC)₃N₅(TTCC)₅N₉(TTCT)₃(TTCC)₁ (TTCT) ₁₂N₁₇(TTCT)₃ (TCCC)₃N₅(TTCC)₅N₉(TTCT)₃(TTCC)₁ (TTCT) ₁₃N₁₇(TTCT)₃ 30 1347 N₁₃(TTCC)₄N₇₀(TTCT)₃N₆(TTCT)₃ N₁₃(TTCC)₄N₇₀(TTCT)₃N₆(TTCT)₃ DYS533 (TATC) ₁₃ (TATC) ₁₂ 34 27 DYS533 (TATC) ₁₃ (TATC) ₁₂ 29 892 DYS533 (TATC) ₁₃ (TATC) ₁₂ 37 905 DYS533 (TATC) ₁₃ (TATC) ₁₄ 18 1039 DYS533 (TATC) ₁₂ (TATC) ₁₃ 42 1054 DYS533 (TATC) ₁₄ (TATC) ₁₅ 34 1158 DYS533 (TATC) ₁₂ (TATC) ₁₃ 21 1166 DYS533 (TATC) ₁₃ (TATC) ₁₂ 40 1281 DYS534 (CTTT)₃N₈ (CTTT) ₁₆N₉(CTTT)₃ (CTTT)₃N₈ (CTTT) ₁₇N₉(CTTT)₃ 37 135 DYS534 (CTTT)₃N₈ (CTTT) ₁₆N₉(CTTT)₃ (CTTT)₃N₈ (CTTT) ₁₇N₉(CTTT)₃ 27 167 DYS534 (CTTT)₃N₈ (CTTT) ₁₅N₉(CTTT)₃ (CTTT)₃N₈ (CTTT) ₁₆N₉(CTTT)₃ 17 235 DYS534 (CTTT)₃N₈ (CTTT) ₁₄N₉(CTTT)₃ (CTTT)₃N₈ (CTTT) ₁₅N₉(CTTT)₃ 41 250 DYS534 (CTTT)₃N₈ (CTTT) ₁₄N₉(CTTT)₃ (CTTT)₃N₈ (CTTT) ₁₅N₉(CTTT)₃ 34 308 DYS534 (CTTT)₃N₈ (CTTT) ₁₇N₉(CTTT)₃ (CTTT)₃N₈ (CTTT) ₁₆N₉(CTTT)₃ 39 419 DYS534 (CTTT)₃N₈ (CTTT) ₁₈N₉(CTTT)₃ (CTTT)₃N₈ (CTTT) ₁₉N₉(CTTT)₃ 28 674 DYS534 (CTTT)₃N₈ (CTTT) ₁₃N₉(CTTT)₃ (CTTT)₃N₈ (CTTT) ₁₄N₉(CTTT)₃ 23 1205 DYS534 (CTTT)₃N₈ (CTTT) ₁₆N₉(CTTT)₃ (CTTT)₃N₈ (CTTT) ₁₇N₉(CTTT)₃ 45 1364 DYS534 (CTTT)₃N₈ (CTTT) ₁₄N₉(CTTT)₃ (CTTT)₃N₈ (CTTT) ₁₃N₉(CTTT)₃ 58 1808 DYS534 (CTTT)₃N₈ (CTTT) ₁₇N₉(CTTT)₃ (CTTT)₃N₈ (CTTT) ₁₈N₉(CTTT)₃ 61 1836 DYS536 (TCCT) ₁₂N₈(TTCT)₄ (TCCT) ₁₃N₈(TTCT)₄ 20 1092 DYS537 (TCTA) ₁₂ (TCTA) ₁₃ 29 609 DYS537 (TCTA) ₁₃ (TCTA) ₁₂ 27 1248 DYS537 (TCTA) ₁₁ (TCTA) ₁₂ 40 1427 DYS539 (TAGA) ₁₁ (TAGA) ₁₀ 63 1902 DYS540 (TTAT) ₁₂ (TTAT) ₁₃ 31 141 DYS540 (TTAT) ₁₂ (TTAT) ₁₁ 59 152 DYS540 (TTAT) ₁₁ (TTAT) ₁₀ 19 682 DYS540 (TTAT) ₁₁ (TTAT) ₁₂ 38 1020 DYS540 (TTAT) ₁₂ (TTAT) ₁₁ 31 1134 DYS541 (TATC) ₁₂(TTC)₁(TATC)₃ (TATC) ₁₃(TTC)₁(TATC)₃ 34 151 DYS541 (TATC) ₁₂(TTC)₁(TATC)₃ (TATC) ₁₁(TTC)₁(TATC)₃ 34 239 DYS541 (TATC) ₁₄(TTC)₁(TATC)₃ (TATC) ₁₃(TTC)₁(TATC)₃ 33 339 DYS541 (TATC) ₁₃(TTC)₁(TATC)₃ (TATC) ₁₂(TTC)₁(TATC)₃ 36 733 DYS541 (TATC) ₁₄(TTC)₁(TATC)₃ (TATC) ₁₃(TTC)₁(TATC)₃ 25 1415 DYS541 (TATC) ₁₂(TTC)₁(TATC)₃ (TATC) ₁₃(TTC)₁(TATC)₃ 64 1843 DYS543 (AGAT)₃ (GATA) ₁₁N₄₂(ATGT)₄(ATGG)₂N₃₅(GAAA)₃ (AGAT)₃ (GATA) ₁₂N₄₂(ATGT)₄(ATGG)2N₃₅(GAAA)₃ 23 16 DYS543 (AGAT)₃ (GATA) ₁₅N₄₂(ATGT)₃(ATGG)₃N₃₅(GAAA)₃ (AGAT)₃ (GATA) ₁₄N₄₂(ATGT)₃(ATGG)₃N₃₅(GAAA)₃ 40 774 DYS543 (AGAT)₃ (GATA) ₁₅N₄₂(ATGT)₃(ATGG)₃N₃₅(GAAA)₃ (AGAT)₃ (GATA) ₁₄N₄₂(ATGT)₃(ATGG)₃N₃₅(GAAA)₃ 33 844 DYS543 (AGAT)₃ (GATA) ₁₂N₄₂(ATGT)₄(ATGG)₂N₃₅(GAAA)₃ (AGAT)₃ (GATA) ₁₁N₄₂(ATGT)₄(ATGG)₂N₃₅(GAAA)₃ 43 939 DYS543 (AGAT)₃ (GATA) ₁₃N₄₂(ATGT)₃(ATGG)₃N₃₅(GAAA)₃ (AGAT)₃ (GATA) ₁₄N₄₂(ATGT)₃(ATGG)₃N₃₅(GAAA)₃ 42 1054 DYS543 (AGAT)₃ (GATA) ₁₅N₄₂(ATGT)₃(ATGG)₃N₃₅(GAAA)₃ (AGAT)₃ (GATA) ₁₆N₄₂(ATGT)₃(ATGG)₃N₃₅(GAAA)₃ Unknown 1063 DYS543 (AGAT)₃ (GATA) ₁₃N₄₂(ATGT)₄(ATGG)₂N₃₅(GAAA)₃ (AGAT)₃ (GATA) ₁₂N₄₂(ATGT)₄(ATGG)₂N₃₅(GAAA)₃ Unknown 1223 DYS543 (AGAT)₃ (GATA) ₁₅N₄₂(ATGT)₃(ATGG)₃N₃₅(GAAA)₃ (AGAT)₃ (GATA) ₁₄N₄₂(ATGT)₃(ATGG)₃N₃₅(GAAA)₃ 31 1229 DYS543 (AGAT)₃ (GATA) ₁₃N₄₂(ATGT)₃(ATGG)₃N₃₅(GAAA)₃ (AGAT)₃ (GATA) ₁₂N₄₂(ATGT)₃(ATGG)₃N₃₅(GAAA)₃ 31 1315 DYS543 (AGAT)₃ (GATA) ₁₁N₄₂(ATGT)₄(ATGG)₂N₃₅(GAAA)₃ (AGAT)₃ (GATA) ₁₂N₄₂(ATGT)₄(ATGG)₂N₃₅(GAAA)₃ Unknown 1591 DYS543 (AGAT)₃ (GATA) ₁₃N₄₂(ATGT)₄(ATGG)₂N₃₅(GAAA)₃ (AGAT)₃ (GATA) ₁₂N₄₂(ATGT)₄(ATGG)₂N₃₅(GAAA)₃ 28 1712 DYS546 (TTCC)₃N₂₃(TTCT)₃N₃₃(TTCC)₃N₁₆ (TTCT) ₁₇ (TTCC)₃N₂₃(TTCT)₃N₃₃(TTCC)₃N₁₆ (TTCT) ₁₈ 34 371 DYS546 (TTCC)₃N₂₃(TTCT)₃N₃₃(TTCC)₃N₁₆ (TTCT) ₁₄ (TTCC)₃N₂₃(TTCT)₃N₃₃(TTCC)₃N₁₆ (TTCT) ₁₃ 20 706 DYS546 (TTCC)₃N₂₃(TTCT)₃N₃₃(TTCC)₃N₁₆ (TTCT) ₁₆ (TTCC)₃N₂₃(TTCT)₃N₃₃(TTCC)₃N₁₆ (TTCT) ₁₇ 20 756 DYS546 (TTCC)₃N₂₃(TTCT)₃N₃₃(TTCC)₃N₁₆ (TTCT) ₁₇ (TTCC)₃N₂₃(TTCT)₃N₃₃(TTCC)₃N₁₆ (TTCT) ₁₆ 31 878 DYS546 (TTCC)₃N₂₃(TTCT)₃N₃₃(TTCC)₃N₁₆ (TTCT) ₁₈ (TTCC)₃N₂₃(TTCT)₃N₃₃(TTCC)₃N₁₆ (TTCT) ₁₇ 23 1119 DYS546 (TTCC)₃N₂₃(TTCT)₃N₃₃(TTCC)₃N₁₆ (TTCT) ₁₆ (TTCC)₃N₂₃(TTCT)₃N₃₃(TTCC)₃N₁₆ (TTCT) ₁₄ 55 1840 DYS547 (CCTT)₁₀T(CTTC)₅N₅₆ (TTTC) ₁₆N₁₀(CCTT)₄ (CCTT)₁₀T(CTTC)₅N₅₆ (TTTC) ₁₇N₁₀(CCTT)₄ 28 1 (TCTC)₁(TTTC)₁₁N₁₄(TTTC)₃ (TCTC)₁(TTTC)₁₁N₁₄(TTTC)₃ DYS547 (CCTT)₁₂T(CTTC)₄N₅₆(TTTC)₁₅N₁₀(CCTT)₄ (CCTT)₁₂T(CTTC)₄N₅₆(TTTC)₁₅N₁₀(CCTT)₄ 46 10 (TCTC)₁ (TTTC) ₁₂N₁₄(TTTC)₃ (TCTC)₁ (TTTC) ₁₃N₁₄(TTTC)₃ DYS547 (CCTT)₁₁T(CTTC)₅N₅₆ (TTTC) ₁₇N₁₀(CCTT)₄ (CCTT)₁₁T(CTTC)₅N₅₆ (TTTC) ₁₈N₁₀(CCTT)₄ 59 152 (TCTC)₁(TTTC)₁₄N₁₄(TTTC)₃ (TCTC)₁(TTTC)₁₄N₁₄(TTTC)₃ DYS547 (CCTT) ₁₃T(CTTC)₅N₅₆(TTTC)₁₆N₁₀(CCTT)₄ (CCTT) ₁₂T(CTTC)₅N₅₆(TTTC)₁₆N₁₀(CCTT)₄ 34 243 (TCTC)₁(TTTC)₁₃N₁₄(TTTC)₃ (TCTC)₁(TTTC)₁₃N₁₄(TTTC)₃ DYS547 (CCTT)₁₃T(CTTC)₅N₅₆(TTTC)₁₄N₁₀(CCTT)₄ (CCTT)₁₃T(CTTC)₅N₅₆(TTTC)₁₄N₁₀(CCTT)₄ 31 268 (TCTC)₁ (TTTC) ₁₂N₁₄(TTTC)₃ (TCTC)₁ (TTTC) ₁₁N₁₄(TTTC)₃ DYS547 (CCTT)₁₂T(CTTC)₄N₅₆(TTTC)₁₇N₁₀(CCTT)₄ (CCTT)₁₂T(CTTC)₄N₅₆(TTTC)₁₇N₁₀(CCTT)₄ 50 270 (TCTC)₁ (TTTC) ₁₂N₁₄(TTTC)₃ (TCTC)₁ (TTTC) ₁₁N₁₄(TTTC)₃ DYS547 (CCTT)₁₀T(CTTC)₅N₅₆ (TTTC) ₁₈N₁₀(CCTT)₄ (CCTT)₁₀T(CTTC)₅N₅₆ (TTTC) ₁₉N₁₀(CCTT)₄ 33 339 (TCTC)₁(TTTC)₁₀N₁₄(TTTC)₃ (TCTC)₁(TTTC)₁₀N₁₄(TTTC)₃ DYS547 (CCTT)₁₂T(CTTC)₅N₅₆(TTTC)₁₇N₁₀(CCTT)₄ (CCTT)₁₂T(CTTC)₅N₅₆(TTTC)₁₇N₁₀(CCTT)₄ 36 378 (TCTC)₁ (TTTC) ₁₁N₁₄(TTTC)₃ (TCTC)₁ (TTTC) ₁₀N₁₄(TTTC)₃ DYS547 (CCTT)₁₃T(CTTC)₄N₅₆ (TTTC) ₁₆N₁₀(CCTT)₄ (CCTT)₁₃T(CTTC)₄N₅₆ (TTTC) ₁₇N₁₀(CCTT)₄ 28 425 (TCTC)₁(TTTC)₁₂N₁₄(TTTC)₃ (TCTC)₁(TTTC)₁₂N₁₄(TTTC)₃ DYS547 (CCTT)₁₃T(CTTC)₅N₅₆ (TTTC) ₁₆N₁₀(CCTT)₄ (CCTT)₁₃T(CTTC)₅N₅₆ (TTTC) ₁₈N₁₀(CCTT)₄ 28 484 (TCTC)₁(TTTC)₁₁N₁₄(TTTC)₃ (TCTC)₁(TTTC)₁₁N₁₄(TTTC)₃ DYS547 (CCTT)₁₂T(CTTC)₄N₅₆ (TTTC) ₁₇N₁₀(CCTT)₄ (CCTT)₁₂T(CTTC)₄N₅₆ (TTTC) ₁₆N₁₀(CCTT)₄ 31 613 (TCTC)₁(TTTC)₁₂N₁₄(TTTC)₃ (TCTC)₁(TTTC)₁₂N₁₄(TTTC)₃ DYS547 (CCTT)₁₂T(CTTC)₄N₅₆(TTTC)₁₅N₁₀(CCTT)₄ (CCTT)₁₂T(CTTC)₄N₅₆(TTTC)₁₅N₁₀(CCTT)₄ 39 654 (TCTC)₁ (TTTC) ₁₂N₁₄(TTTC)₃ (TCTC)₁ (TTTC) ₁₁N₁₄(TTTC)₃ DYS547 (CCTT)₁₂T(CTTC)₅N₅₆ (TTTC) ₁₅N₁₀(CCTT)₄ (CCTT)₁₂T(CTTC)₅N₅₆ (TTTC) ₁₄N₁₀(CCTT)₄ 27 710 (TCTC)₁(TTTC)₁₂N₁₄(TTTC)₃ (TCTC)₁(TTTC)₁₂N₁₄(TTTC)₃ DYS547 (CCTT)₁₃T(CTTC)₅N₅₆ (TTTC) ₁₅N₁₀(CCTT)₄ (CCTT)₁₃T(CTTC)₅N₅₆ (TTTC) ₁₄N₁₀(CCTT)₄ 25 711 (TCTC)₁(TTTC)₁₁N₁₄(TTTC)₃ (TCTC)₁(TTTC)₁₁N₁₄(TTTC)₃ DYS547 (CCTT)₁₀T(CTTC)₅N₅₆ (TTTC) ₁₈N₁₀(CCTT)₄ (CCTT)₁₀T(CTTC)₅N₅₆ (TTTC) ₁₇N₁₀(CCTT)₄ 59 846 (TCTC)₁(TTTC)₁₀N₁₄(TTTC)₃ (TCTC)₁(TTTC)₁₀N₁₄(TTTC)₃ DYS547 (CCTT)₁₂T(CTTC)₄N₅₆ (TTTC) ₁₆N₁₀(CCTT)₄ (CCTT)₁₂T(CTTC)₄N₅₆ (TTTC) ₁₇N₁₀(CCTT)₄ 37 904 (TCTC)₁(TTTC)₁₂N₁₄(TTTC)₃ (TCTC)₁(TTTC)₁₂N₁₄(TTTC)₃ DYS547 (CCTT)₁₂T(CTTC)₄N₅₆ (TTTC) ₁₈N₁₀(CCTT)₄ (CCTT)₁₂T(CTTC)₄N₅₆ (TTTC) ₁₉N₁₀(CCTT)₄ 22 986 (TCTC)₁(TTTC)₁₃N₁₄(TTTC)₃ (TCTC)₁(TTTC)₁₃N₁₄(TTTC)₃ DYS547 (CCTT)₁₂T(CTTC)₅N₅₆ (TTTC) ₂₂N₁₀(CCTT)₄ (CCTT)₁₂T(CTTC)₅N₅₆ (TTTC) ₂₁N₁₀(CCTT)₄ 55 1022 (TCTC)₁(TTTC)₉N₁₄(TTTC)₃ (TCTC)₁(TTTC)₉N₁₄(TTTC)₃ DYS547 (CCTT)₁₂T(CTTC)₄N₅₆(TTTC)₁₆N₁₀(CCTT)₄ (CCTT)₁₂T(CTTC)₄N₅₆(TTTC)₁₆N₁₀(CCTT)₄ 43 1153 (TCTC)₁ (TTTC) ₁₃N₁₄(TTTC)₃ (TCTC)₁ (TTTC) ₁₄N₁₄(TTTC)₃ DYS547 (CCTT)₁₂T(CTTC)₄N₅₆ (TTTC) ₁₉N₁₀(CCTT)₄ (CCTT)₁₂T(CTTC)₄N₅₆ (TTTC) ₁₈N₁₀(CCTT)₄ 31 1229 (TCTC)₁(TTTC)₁₂N₁₄(TTTC)₃ (TCTC)₁(TTTC)₁₂N₁₄(TTTC)₃ DYS547 (CCTT)₁₂T(CTTC)₄N₅₆(TTTC)₁₆N₁₀(CCTT)₄ (CCTT)₁₂T(CTTC)₄N₅₆(TTTC)₁₆N₁₀(CCTT)₄ 29 1276 (TCTC)₁ (TTTC) ₁₃N₁₄(TTTC)₃ (TCTC)₁ (TTTC) ₁₄N₁₄(TTTC)₃ DYS547 (CCTT)₁₂T(CTTC)₄N₅₆ (TTTC) ₁₈N₁₀(CCTT)₄ (CCTT)₁₂T(CTTC)₄N₅₆ (TTTC) ₁₉N₁₀(CCTT)₄ 28 1294 (TCTC)₁(TTTC)₁₂N₁₄(TTTC)₃ (TCTC)₁(TTTC)₁₂N₁₄(TTTC)₃ DYS547 (CCTT)₁₁T(CTTC)₄N₅₆(TTTC)₁₆N₁₀(CCTT)₄ (CCTT)₁₁T(CTTC)₄N₅₆(TTTC)₁₆N₁₀(CCTT)₄ 30 1297 (TCTC)₁ (TTTC) ₁₂N₁₄(TTTC)₃ (TCTC)₁ (TTTC) ₁₃N₁₄(TTTC)₃ DYS547 (CCTT)₁₁T(CTTC)₅N₅₆(TTTC)₁₅N₁₀(CCTT)₄ (CCTT)₁₁T(CTTC)₅N₅₆(TTTC)₁₅N₁₀(CCTT)₄ 32 1321 (TCTC)₁ (TTTC) ₁₁N₁₄(TTTC)₃ (TCTC)₁ (TTTC) ₁₂N₁₄(TTTC)₃ DYS547 (CCTT)₁₂T(CTTC)₅N₅₆(TTTC)₁₅N₁₀(CCTT)₄ (CCTT)₁₂T(CTTC)₅N₅₆(TTTC)₁₅N₁₀(CCTT)₄ 41 1379 (TCTC)₁ (TTTC) ₁₂N₁₄(TTTC)₃ (TCTC)₁ (TTTC) ₁₃N₁₄(TTTC)₃ DYS547 (CCTT)₁₀T(CTTC)₅N₅₆ (TTTC) ₁₈N₁₀(CCTT)₄ (CCTT)₁₀T(CTTC)₅N₅₆ (TTTC) ₁₉N₁₀(CCTT)₄ 24 1466 (TCTC)₁(TTTC)₁₀N₁₄(TTTC)₃ (TCTC)₁(TTTC)₁₀N₁₄(TTTC)₃ DYS547 (CCTT)₁₀T(CTTC)₅N₅₆(TTTC)₁₆N₁₀(CCTT)₄ (CCTT)₁₀T(CTTC)₅N₅₆(TTTC)₁₆N₁₀(CCTT)₄ 42 1485 (TCTC)₁ (TTTC) ₁₀N₁₄(TTTC)₃ (TCTC)₁ (TTTC) ₁₁N₁₄(TTTC)₃ DYS547 (CCTT)₁₂T(CTTC)₅N₅₆ (TTTC) ₁₅N₁₀(CCTT)₄ (CCTT)₁₂T(CTTC)₅N₅₆ (TTTC) ₁₆N₁₀(CCTT)₄ 29 1491 (TCTC)₁(TTTC)₁₃N₁₄(TTTC)₃ (TCTC)₁(TTTC)₁₃N₁₄(TTTC)₃ DYS547 (CCTT)₁₂T(CTTC)₄N₅₆ (TTTC) ₁₆N₁₀(CCTT)₄ (CCTT)₁₂T(CTTC)₄N₅₆ (TTTC) ₁₇N₁₀(CCTT)₄ 23 1510 (TCTC)₁(TTTC)₁₂N₁₄(TTTC)₃ (TCTC)₁(TTTC)₁₂N₁₄(TTTC)₃ DYS547 (CCTT)₁₂T(CTTC)₅N₅₆(TTTC)₁₆N₁₀(CCTT)₄ (CCTT)₁₂T(CTTC)₅N₅₆(TTTC)₁₆N₁₀(CCTT)₄ 38 1524 (TCTC)₁ (TTTC) ₁₁N₁₄(TTTC)₃ (TCTC)₁ (TTTC) ₁₀N₁₄(TTTC)₃ DYS547 (CCTT)₁₂T(CTTC)₅N₅₆(TTTC)₁₀N₁₀(CCTT)₄ (CCTT)₁₂T(CTTC)₅N₅₆(TTTC)₁₀N₁₀(CCTT)₄ 36 1582 (TCTC)₁₍ (TTTC) ₁₇N₁₄(TTTC)₃ (TCTC)₁ (TTTC) ₁₆N₁₄(TTTC)₃ DYS547 (CCTT)₁₂T(CTTC)₅N₅₆ (TTTC) ₁₆N₁₀(CCTT)₄ (CCTT)₁₂T(CTTC)₅N₅₆ (TTTC) ₁₇N₁₀(CCTT)₄ 28 1640 (TCTC)₁(TTTC)₁₃N₁₄(TTTC)₃ (TCTC)₁(TTTC)₁₃N₁₄(TTTC)₃ DYS547 (CCTT)₁₂T(CTTC)₄N₅₆ (TTTC) ₁₅N₁₀(CCTT)₄ (CCTT)₁₂T(CTTC)₄N₅₆ (TTTC) ₁₄N₁₀(CCTT)₄ 22 1648 (TCTC)₁(TTTC)₁₂N₁₄(TTTC)₃ (TCTC)₁(TTTC)₁₂N₁₄(TTTC)₃ DYS547 (CCTT)₁₂T(CTTC)₅N₅₆ (TTTC) ₁₆N₁₀(CCTT)₄ (CCTT)₁₂T(CTTC)₅N₅₆ (TTTC) ₁₇N₁₀(CCTT)₄ 37 1663 (TCTC)₁(TTTC)₁₂N₁₄(TTTC)₃ (TCTC)₁(TTTC)₁₂N₁₄(TTTC)₃ DYS547 (CCTT)₁₂T(CTTC)₄N₅₆ (TTTC) ₁₆N₁₀(CCTT)₄ (CCTT)₁₂T(CTTC)₄N₅₆ (TTTC) ₁₇N₁₀(CCTT)₄ Unknown 1723 (TCTC)₁(TTTC)₁₂N₁₄(TTTC)₃ (TCTC)₁(TTTC)₁₂N₁₄(TTTC)₃ DYS547 (CCTT)₁₂T(CTTC)₅N₅₆ (TTTC) ₁₇N₁₀(CCTT)₄ (CCTT)₁₂T(CTTC)₅N₅₆ (TTTC) ₁₆N₁₀(CCTT)₄ 54 1860 (TCTC)₁(TTTC)₁₂N₁₄(TTTC)₃ (TCTC)₁(TTTC)₁₂N₁₄(TTTC)₃ DYS547 (CCTT)₁₀T(CTTC)₅N₅₆(TTTC)₁₆N₁₀(CCTT)₄ (CCTT)₁₀T(CTTC)₅N₅₆(TTTC)₁₆N₁₀(CCTT)₄ 53 1871 (TCTC)₁ (TTTC) ₁₃N₁₄(TTTC)₃ (TCTC)₁ (TTTC) ₁₂N₁₄(TTTC)₃ DYS547 (CCTT)₁₂T(CTTC)₅N₅₆ (TTTC) ₁₆N₁₀(CCTT)₄ (CCTT)₁₂T(CTTC)₅N₅₆ (TTTC) ₁₅N₁₀(CCTT)₄ 55 1910 (TCTC)₁(TTTC)₁₁N₁₄(TTTC)₃ (TCTC)₁(TTTC)₁₁N₁₄(TTTC)₃ DYS547 (CCTT)₁₂T(CTTC)₅N₅₆(TTTC)₁₄N₁₀(CCTT)₄ (CCTT)₁₂T(CTTC)₅N₅₆(TTTC)₁₄N₁₀(CCTT)₄ 65 1920 (TCTC)₁ (TTTC) ₁₁N₁₄(TTTC)₃ (TCTC)₁ (TTTC) ₁₂N₁₄(TTTC)₃ DYS549 (GATA) ₁₃ (GATA) ₁₂ 30 87 DYS549 (GATA) ₁₃ (GATA) ₁₂ 47 113 DYS549 (GATA) ₁₂ (GATA) ₁₁ 27 119 DYS549 (GATA) ₁₂ (GATA) ₁₃ 38 336 DYS549 (GATA) ₁₄ (GATA) ₁₃ 43 472 DYS549 (GATA) ₁₂ (GATA) ₁₁ 25 517 DYS549 (GATA) ₁₂ (GATA) ₁₁ 22 625 DYS551 (AGAT) ₁₅N₈(AGAC)₃(AGGT)₁(AGAT)₄ (AGAT) ₁₄N₈(AGAC)₃(AGGT)₁(AGAT)₄ 21 436 DYS551 (AGAT) ₁₄N₈(AGAC)₃(AGGT)₁(AGAT)₄ (AGAT) ₁₃N₈(AGAC)₃(AGGT)₁(AGAT)₄ 22 604 DYS551 (AGAT) ₁₅N₈(AGAC)₃(AGGT)₁(AGAT)₄ (AGAT) ₁₄N₈(AGAC)₃(AGGT)₁(AGAT)₄ 41 862 DYS551 (AGAT) ₁₄N₈(AGAC)₃(AGGT)₁(AGAT)₄ (AGAT) ₁₃N₈(AGAC)₃(AGGT)₁(AGAT)₄ 51 1212 DYS551 (AGAT) ₁₃N₈(AGAC)₃(AGGT)₁(AGAT)₄ (AGAT) ₁₄N₈(AGAC)₃(AGGT)₁(AGAT)₄ 27 1671 DYS552 (TCTA)₃(TCTG)₁ (TCTA) ₉N₄₀(TCTA)₁₅ (TCTA)₃(TCTG)₁ (TCTA) ₇N₄₀(TCTA)₁₅ 25 471 DYS552 (TCTA)₃(TCTG)₁(TCTA)₁0N₄₀ (TCTA) ₁₅ (TCTA)₃(TCTG)₁(TCTA)₁₀N₄₀ (TCTA) ₁₆ 59 846 DYS552 (TCTA)₃(TCTG)₁(TCTA)₁₀N₄₀ (TCTA) ₁₄ (TCTA)₃(TCTG)₁(TCTA)₁₀N₄₀ (TCTA) ₁₅ 18 847 DYS552 (TCTA)₃(TCTG)₁ (TCTA) ₁₁N₄₀(TCTA)₁₄ (TCTA)₃(TCTG)₁ (TCTA) ₁₂N₄₀(TCTA)₁₄ 31 1486 DYS554 (TAAA) ₁₀ (TAAA) ₁₁ 37 1277 DYS556 (AAAT) ₁₂ (AAAT) ₁₁ 30 1101 DYS556 (AAAT) ₁₁ (AAAT) ₁₂ 21 1448 DYS557 (TTTC)₄(TTCTC)₁(TTTC)₄(TTC)₁ (TTTC) ₁₆ (TTTC)₄(TTCTC)₁(TTTC)₄(TTC)₁ (TTTC) ₁₅ 24 17 DYS557 (TTTC)₄(TTCTC)₁(TTTC)₄(TTC)₁ (TTTC) ₁₆ (TTTC)₄(TTCTC)₁(TTTC)₄(TTC)₁ (TTTC) ₁₅ 23 52 DYS557 (TTTC)₄(TTCTC)₁(TTTC)₄(TTC)₁ (TTTC) ₁₅ (TTTC)₄(TTCTC)₁(TTTC)₄(TTC)₁ (TTTC) ₁₆ 34 394 DYS557 (TTTC)₄(TTCTC)₁(TTTC)₄(TTC)₁ (TTTC) ₁₅ (TTTC)₄(TTCTC)₁(TTTC)₄(TTC)₁ (TTTC) ₁₆ 38 589 DYS557 (TTTC)₄(TTCTC)₁(TTTC)₄(TTC)₁ (TTTC) ₁₇ (TTTC)₄(TTCTC)₁(TTTC)₄(TTC)₁ (TTTC) ₁₆ 38 1494 DYS557 (TTTC)₄(TTCTC)₁(TTTC)₄(TTC)₁ (TTTC) ₁₅ (TTTC)₄(TTCTC)₁(TTTC)₄(TTC)₁ (TTTC) ₁₆ 17 1517 DYS559 (TAAA) ₉ (TAAA) ₈ 27 1357 DYS561 (GATA) ₁₃(GACA)₄ (GATA) ₁₂(GACA)₄ 34 359 DYS565 (ATAA) ₁₃ (ATAA) ₁₂ 34 101 DYS565 (ATAA) ₁₃ (ATAA) ₁₂ 43 624 DYS565 (ATAA) ₁₃ (ATAA) ₁₄ 27 1673 DYS568 (AAAT) ₁₂ (AAAT) ₁₃ 35 1547 DYS569 (ATTT) ₁₂ (ATTT) ₁₁ 31 598 DYS569 (ATTT) ₁₂ (ATTT) ₁₁ 21 1053 DYS570 (TTTC) ₁₇ (TTTC) ₁₆ 34 92 DYS570 (TTTC) ₁₉ (TTTC) ₂₀ 39 112 DYS570 (TTTC) ₁₉ (TTTC) ₁₈ 20 240 DYS570 (TTTC) ₂₀ (TTTC) ₁₉ 37 293 DYS570 (TTTC) ₁₇ (TTTC) ₁₈ 41 313 DYS570 (TTTC) ₁₉ (TTTC) ₁₇ 16 316 DYS570 (TTTC) ₁₉ (TTTC) ₁₈ 25 317 DYS570 (TTTC) ₂₀ (TTTC) ₂₁ 32 614 DYS570 (TTTC) ₂₀ (TTTC) ₂₁ 24 855 DYS570 (TTTC) ₂₀ (TTTC) ₁₉ 30 867 DYS570 (TTTC)₂₁ (TTTC) ₂₂ 22 922 DYS570 (TTTC) ₁₈ (TTTC) ₁₉ 36 1061 DYS570 (TTTC) ₁₉ (TTTC) ₂₀ 20 1253 DYS570 (TTTC) ₁₆ (TTTC) ₁₅ 41 1256 DYS570 (TTTC) ₂₁ (TTTC) ₂₀ 45 1364 DYS570 (TTTC) ₁₇ (TTTC) ₁₈ 54 1895 DYS570 (TTTC) ₁₉ (TTTC) ₁₈ 66 1901 DYS572 (AAAT) ₁₁ (AAAT) ₁₀ 35 735 DYS572 (AAAT) ₁₁ (AAAT) ₁₀ 24 1342 DYS572 (AAAT) ₁₁ (AAAT) ₁₀ 28 1696 DYS574 (TTAT) ₁₀ (TTAT) ₉ 43 1818 DYS576 (AAAG) ₁₇ (AAAG) ₁₈ 28 153 DYS576 (AAAG) ₁₉ (AAAG) ₁₈ 34 236 DYS576 (AAAG) ₁₇ (AAAG) ₁₈ 34 243 DYS576 (AAAG) ₁₈ (AAAG) ₁₇ 47 347 DYS576 (AAAG) ₁₉ (AAAG) ₁₈ 17 635 DYS576 (AAAG) ₁₉ (AAAG) ₁₈ 37 715 DYS576 (AAAG) ₂₀ (AAAG) ₂₁ 23 716 DYS576 (AAAG) ₁₈ (AAAG) ₁₇ 38 719 DYS576 (AAAG) ₂₀ (AAAG) ₂₁ 29 789 DYS576 (AAAG) ₂₀ (AAAG) ₁₉ 50 884 DYS576 (AAAG) ₁₇ (AAAG) ₁₈ 42 1054 DYS576 (AAAG) ₁₉ (AAAG) ₁₈ 36 1061 DYS576 (AAAG) ₁₈ (AAAG) ₁₉ Unknown 1200 DYS576 (AAAG) ₁₈ (AAAG) ₁₉ 40 1204 DYS576 (AAAG) ₁₈ (AAAG) ₁₉ 51 1212 DYS576 (AAAG) ₁₈ (AAAG) ₁₇ Unknown 1224 DYS576 (AAAG) ₁₈ (AAAG) ₁₉ Unknown 1265 DYS576 (AAAG) ₁₈ (AAAG) ₁₉ 38 1278 DYS576 (AAAG) ₁₇ (AAAG) ₁₆ 22 1403 DYS576 (AAAG) ₁₉ (AAAG) ₁₈ 42 1411 DYS576 (AAAG) ₁₈ (AAAG) ₁₇ 26 1440 DYS576 (AAAG) ₁₈ (AAAG) ₁₉ 47 1675 DYS576 (AAAG) ₁₈ (AAAG) ₁₉ 55 1844 DYS576 (AAAG) ₂₀ (AAAG) ₁₉ 54 1939 DYS578 (AAAT) ₈ (AAAT) ₉ Unknown 1353 DYS585 (TTATG) ₉ (TTATG) ₁₀ 35 794 DYS585 (TTATG) ₉ (TTATG) ₈ 26 1105 DYS585 (TTATG) ₉ (TTATG) ₁₀ 17 1109 DYS587 (CAATA) ₁₁[(CAGTA)₁(CAATA)₁]₃ (CAATA) ₁₀[(CAGTA)₁(CAATA)₁]₃ 24 83 DYS587 (CAATA) ₁₁[(CAGTA)₁(CAATA)₁]₃ (CAATA) ₁₂[(CAGTA)₁(CAATA)₁]₃ 59 152 DYS587 (CAATA) ₁₂[(CAGTA)₁(CAATA)₁]₃ (CAATA) ₁₁[(CAGTA)₁(CAATA)₁]₃ 25 260 DYS587 (CAATA) ₁₂[(CAGTA)₁(CAATA)₁]₃ (CAATA) ₁₃[(CAGTA)₁(CAATA)₁]₃ 63 917 DYS593 (AAAAC)₄ (AAAAT) ₈ (AAAAC)₄ (AAAAT) ₇ 26 1082 DYS593 (AAAAC)₄ (AAAAT) ₈ (AAAAC)₄ (AAAAT) ₉ Unknown 1353 DYS594 (AAATA) ₁₀ (AAATA) ₁₁ 31 1134 DYS611 (TTC)₅N₉(TTC)₄(CTC)₁(TTC)₃N₉(TTC)₅(CTC)₁(TTC)₃N₁₅ (TTC)₅N₉(TTC)₄(CTC)₁(TTC)₃N₉(TTC)₅(CTC)₁(TTC)₃N₁₅ 30 99 (TTC)₄(CT)₁(TTC)₃(CTC)₁(TTC)₃N₂₀(TTC)₃T(TTC)₄N₇ (TTC)₄(CT)₁(TTC)₃(CTC)₁(TTC)₃N₂₀(TTC)₃T(TTC)₄N₇ (TTC)₃N₉(TTC)₄(TCC)₁ (TTC) ₁₉N₂₃(TTC)₄N₄ (TTC)₃N₉(TTC)₄(TCC)₁ (TTC) ₂₀N₂₃(TTC)₄N₄ [(TTC)₁(CTC)₁]₂[(CTC)₁(TTC)₁]₃ [(TTC)₁(CTC)₁]₂[(CTC)₁(TTC)₁]₃ DYS611 (TTC)₅N₉(TTC)₄(CTC)₁(TTC)₃N₉(TTC)₅(CTC)₁(TTC)₃N₁₅ (TTC)₅N₉(TTC)₄(CTC)₁(TTC)₃N₉(TTC)₅(CTC)₁(TTC)₃N₁₅ 31 164 (TTC)₄(CT)₁(TTC)₃(CTC)₁(TTC)₃N₂₀(TTC)₃T(TTC)₄N₇ (TTC)₄(CT)₁(TTC)₃(CTC)₁(TTC)₃N₂₀(TTC)₃T(TTC)₄N₇ (TTC)₃N₉(TTC)₄(TCC)₁ (TTC) ₁₇N₂₃(TTC)₄N₄ (TTC)₃N₉(TTC)₄(TCC)₁ (TTC) ₁₆N₂₃(TTC)₄N₄ [(TTC)₁(CTC)₁]₂[(CTC)₁(TTC)₁]₃ [(TTC)₁(CTC)₁]₂[(CTC)₁(TTC)₁]₃ DYS611 (TTC)₅N₉(TTC)₄(CTC)₁(TTC)₃N₉(TTC)₅(CTC)₁(TTC)₃N₁₅ (TTC)₅N₉(TTC)₄(CTC)₁(TTC)₃N₉(TTC)₅(CTC)₁(TTC)₃N₁₅ 20 254 (TTC)₄(CT)₁(TTC)₃(CTC)₁(TTC)₃N₂₀(TTC)₃T(TTC)₄N₇ (TTC)₄(CT)₁(TTC)₃(CTC)₁(TTC)₃N₂₀(TTC)₃T(TTC)₄N₇ (TTC)₃N₉(TTC)₄(TCC)₁ (TTC) ₁₈N₂₃(TTC)₄N₄ (TTC)₃N₉(TTC)₄(TCC)₁ (TTC) ₁₆N₂₃(TTC)₄N₄ [(TTC)₁(CTC)₁]₂[(CTC)₁(TTC)₁]₃ [(TTC)₁(CTC)₁]₂[(CTC)₁(TTC)₁]₃ DYS611 (TTC)₅N₉(TTC)₄(CTC)₁(TTC)₃N₉(TTC)₅(CTC)₁(TTC)₃N₁₅ (TTC)₅N₉(TTC)₄(CTC)₁(TTC)₃N₉(TTC)₅(CTC)₁(TTC)₃N₁₅ 25 517 (TTC)₄(CT)₁(TTC)₃(CTC)₁(TTC)₃N₂₀(TTC)₃T(TTC)₄N₇ (TTC)₄(CT)₁(TTC)₃(CTC)₁(TTC)₃N₂₀(TTC)₃T(TTC)₄N₇ (TTC)₃N₉(TTC)₄(TCC)₁ (TTC) ₁₅N₂₃(TTC)₄N₄ (TTC)₃N₉(TTC)₄(TCC)₁ (TTC) ₁₄N₂₃(TTC)₄N₄ [(TTC)₁(CTC)₁]₂[(CTC)₁(TTC)₁]₃ [(TTC)₁(CTC)₁]₂[(CTC)₁(TTC)₁]₃ DYS611 (TTC)₅N₉(TTC)₄(CTC)₁(TTC)₃N₉(TTC)₅(CTC)₁(TTC)₃N₁₅ (TTC)₅N₉(TTC)₄(CTC)₁(TTC)₃N₉(TTC)₅(CTC)₁(TTC)₃N₁₅ 18 956 (TTC)₄(CT)₁(TTC)₃(CTC)₁(TTC)₃N₂₀(TTC)₃T(TTC)₄N₇ (TTC)₄(CT)₁(TTC)₃(CTC)₁(TTC)₃N₂₀(TTC)₃T(TTC)₄N₇ (TTC)₃N₉(TTC)₄(TCC)₁ (TTC) ₁₇N₂₃(TTC)₄N₄ (TTC)₃N₉(TTC)₄(TCC)₁ (TTC) ₁₈N₂₃(TTC)₄N₄ [(TTC)₁(CTC)₁]₂[(CTC)₁(TTC)₁]₃ [(TTC)₁(CTC)₁]₂[(CTC)₁(TTC)₁]₃ DYS611 (TTC)₅N₉(TTC)₄(CTC)₁(TTC)₃N₉(TTC)₅(CTC)₁(TTC)₃N₁₅ (TTC)₅N₉(TTC)₄(CTC)₁(TTC)₃N₉(TTC)₅(CTC)₁(TTC)₃N₁₅ 48 969 (TTC)₄(CT)₁(TTC)₃(CTC)₁(TTC)₃N₂₀(TTC)₃T(TTC)₄N₇ (TTC)₄(CT)₁(TTC)₃(CTC)₁(TTC)₃N₂₀(TTC)₃T(TTC)₄N₇ (TTC)₃N₉(TTC)₄(TCC)₁ (TTC) ₁₆N₂₃(TTC)₄N₄ (TTC)₃N₉(TTC)₄(TCC)₁ (TTC) ₁₅N₂₃(TTC)₄N₄ [(TTC)₁(CTC)₁]₂[(CTC)₁(TTC)₁]₃ [(TTC)₁(CTC)₁]₂[(CTC)₁(TTC)₁]₃ DYS611 (TTC)₅N₉(TTC)₄(CTC)₁(TTC)₃N₉(TTC)₅(CTC)₁(TTC)₃N₁₅ (TTC)₅N₉(TTC)₄(CTC)₁(TTC)₃N₉(TTC)₅(CTC)₁(TTC)₃N₁₅ 34 990 (TTC)₄(CT)₁(TTC)₃(CTC)₁(TTC)₃N₂₀(TTC)₃T(TTC)₄N₇ (TTC)₄(CT)₁(TTC)₃(CTC)₁(TTC)₃N₂₀(TTC)₃T(TTC)₄N₇ (TTC)₃N₉(TTC)₄(TCC)₁ (TTC) ₁₆N₂₃(TTC)₄N₄ (TTC)₃N₉(TTC)₄(TCC)₁ (TTC) ₁₅N₂₃(TTC)₄N₄ [(TTC)₁(CTC)₁]₂[(CTC)₁(TTC)₁]₃ [(TTC)₁(CTC)₁]₂[(CTC)₁(TTC)₁]₃ DYS611 (TTC)₅N₉(TTC)₄(CTC)₁(TTC)₃N₉(TTC)₅(CTC)₁(TTC)₃N₁₅ (TTC)₅N₉(TTC)₄(CTC)₁(TTC)₃N₉(TTC)₅(CTC)₁(TTC)₃N₁₅ 45 1171 (TTC)₄(CT)₁(TTC)₃(CTC)₁(TTC)₃N₂₀(TTC)₃T(TTC)₄N₇ (TTC)₄(CT)₁(TTC)₃(CTC)₁(TTC)₃N₂₀(TTC)₃T(TTC)₄N₇ (TTC)₃N₉(TTC)₄(TCC)₁ (TTC) ₁₆N₂₃(TTC)₄N₄ (TTC)₃N₉(TTC)₄(TCC)₁ (TTC) ₁₅N₂₃(TTC)₄N₄ [(TTC)₁(CTC)₁]₂[(CTC)₁(TTC)₁]₃ [(TTC)₁(CTC)₁]₂[(CTC)₁(TTC)₁]₃ DYS611 (TTC)₅N₉(TTC)₄(CTC)₁(TTC)₃N₉(TTC)₅(CTC)₁(TTC)₃N₁₅ (TTC)₅N₉(TTC)₄(CTC)₁(TTC)₃N₉(TTC)₅(CTC)₁(TTC)₃N₁₅ 21 1216 (TTC)₄(CT)₁(TTC)₃(CTC)₁(TTC)₃N₂₀(TTC)₃T(TTC)₄N₇ (TTC)₄(CT)₁(TTC)₃(CTC)₁(TTC)₃N₂₀(TTC)₃T(TTC)₄N₇ (TTC)₃N₉(TTC)₄(TCC)₁ (TTC) ₁₆N₂₃(TTC)₄N₄ (TTC)₃N₉(TTC)₄(TCC)₁ (TTC) ₁₄N₂₃(TTC)₄N₄ [(TTC)₁(CTC)₁]₂[(CTC)₁(TTC)₁]₃ [(TTC)₁(CTC)₁]₂[(CTC)₁(TTC)₁]₃ DYS611 (TTC)₅N₉(TTC)₄(CTC)₁(TTC)₃N₉(TTC)₅(CTC)₁(TTC)₃N₁₅ (TTC)₅N₉(TTC)₄(CTC)₁(TTC)₃N₉(TTC)₅(CTC)₁(TTC)₃N₁₅ 40 1281 (TTC)₄(CT)₁(TTC)₃(CTC)₁(TTC)₃N₂₀(TTC)₃T(TTC)₄N₇ (TTC)₄(CT)₁(TTC)₃(CTC)₁(TTC)₃N₂₀(TTC)₃T(TTC)₄N₇ (TTC)₃N₉(TTC)₄(TCC)₁ (TTC) ₁₇N₂₃(TTC)₄N₄ (TTC)₃N₉(TTC)₄(TCC)₁ (TTC) ₁₆N₂₃(TTC)₄N₄ [(TTC)₁(CTC)₁]₂[(CTC)₁(TTC)₁]₃ [(TTC)₁(CTC)₁]₂[(CTC)₁(TTC)₁]₃ DYS611 (TTC)₅N₉(TTC)₄(CTC)₁(TTC)₃N₉(TTC)₅(CTC)₁(TTC)₃N₁₅ (TTC)₅N₉(TTC)₄(CTC)₁(TTC)₃N₉(TTC)₅(CTC)₁(TTC)₃N₁₅ 30 1401 (TTC)₄(CT)₁(TTC)₃(CTC)₁(TTC)₃N₂₀(TTC)₃T(TTC)₄N₇ (TTC)₄(CT)₁(TTC)₃(CTC)₁(TTC)₃N₂₀(TTC)₃T(TTC)₄N₇ (TTC)₃N₉(TTC)₄(TCC)₁ (TTC) ₁₅N₂₃(TTC)₄N₄ (TTC)₃N₉(TTC)₄(TCC)₁ (TTC) ₁₄N₂₃(TTC)₄N₄ [(TTC)₁(CTC)₁]₂[(CTC)₁(TTC)₁]₃ [(TTC)₁(CTC)₁]₂[(CTC)₁(TTC)₁]₃ DYS611 (TTC)₅N₉(TTC)₄(CTC)₁(TTC)₃N₉(TTC)₅(CTC)₁(TTC)₃N₁₅ (TTC)₅N₉(TTC)₄(CTC)₁(TTC)₃N₉(TTC)₅(CTC)₁(TTC)₃N₁₅ 53 1839 (TTC)₄(CT)₁(TTC)₃(CTC)₁(TTC)₃N₂₀(TTC)₃T(TTC)₄N₇ (TTC)₄(CT)₁(TTC)₃(CTC)₁(TTC)₃N₂₀(TTC)₃T(TTC)₄N₇ (TTC)₃N₉(TTC)₄(TCC)₁ (TTC) ₁₉N₂₃(TTC)₄N₄ (TTC)₃N₉(TTC)₄(TCC)₁ (TTC) ₁₈N₂₃(TTC)₄N₄ [(TTC)₁(CTC)₁]₂[(CTC)₁(TTC)₁]₃ [(TTC)₁(CTC)₁]₂[(CTC)₁(TTC)₁]₃ DYS612 (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₇ (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₆ 25 4 DYS612 (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₅ (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₆ 34 124 DYS612 (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₆ (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₅ 33 127 DYS612 (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₇ (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₈ 31 141 DYS612 (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₅ (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₄ 49 161 DYS612 (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₅ (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₄ 26 248 DYS612 (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₆ (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₇ 34 258 DYS612 (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₅ (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₄ 21 593 DYS612 (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₅ (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₄ 53 659 DYS612 (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₄ (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₅ 19 696 DYS612 (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₅ (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₆ 32 770 DYS612 (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₂ (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₁ 36 830 DYS612 (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₅ (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₆ 35 875 DYS612 (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₆ (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₇ 24 933 DYS612 (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₄ (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₅ 27 1044 DYS612 (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₈ (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₇ 21 1053 DYS612 (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₅ (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₄ Unknown 1224 DYS612 (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₇ (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₆ 49 1335 DYS612 (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₆ (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₅ 23 1359 DYS612 (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₅ (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₄ 20 1460 DYS612 (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₃ (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₄ 36 1582 DYS612 (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₃ (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₄ Unknown 1613 DYS612 (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₇ (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₆ 41 1786 DYS612 (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₈ (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₇ 32 1792 DYS612 (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₅ (CCT)₅(CTT)₁(TCT)₄(CCT)₁ (TCT) ₂₆ 51 1888 DYS614 (CTT)₄(CCT)₁(CTT)₃N₁₅(CCT)₄(CTT)₄(CCT)₁(CTT)₃N₁₈ (CTT)₄(CCT)₁(CTT)₃N₁₅(CCT)₄(CTT)₄(CCT)₁(CTT)₃N₁₈ 22 219 (CCT)₃(CTT)₅N₂₀[(CTT)₁(CTG)₁]₃(CT)₁ (CTT) ₁₉N₈(CTT)₄ (CCT)₃(CTT)₅N₂₀[(CTT)₁(CTG)₁]₃(CT)₁ (CTT) ₁₈N₈(CTT)₄ [(CTC)₁(CTT)₁]₃[(CTC)₁(TTT)₁]₁(CTT)₅ [(CTC)₁(CTT)₁]₃[(CTC)₁(TTT)₁]₁(CTT)₅ DYS614 (CTT)₄(CCT)₁(CTT)₃N₁₅(CCT)₄(CTT)₄(CCT)₁(CTT)₃N₁₈ (CTT)₄(CCT)₁(CTT)₃N₁₅(CCT)₄(CTT)₄(CCT)₁(CTT)₃N₁₈ 24 855 (CCT)₃(CTT)₅N₂₀[(CTT)₁(CTG)₁]₃(CT)₁ (CTT) ₂₀N₈(CTT)₄ (CCT)₃(CTT)₅N₂₀[(CTT)₁(CTG)₁]₃(CT)₁ (CTT) ₁₉N₈(CTT)₄ [(CTC)₁(CTT)₁]₃[(CTC)₁(TTT)₁]₁(CTT)₅ [(CTC)₁(CTT)₁]₃[(CTC)₁(TTT)₁]₁(CTT)₅ DYS614 (CTT)₄(CCT)₁(CTT)₃N₁₅(CCT)₄(CTT)₄(CCT)₁(CTT)₃N₁₈ (CTT)₄(CCT)₁(CTT)₃N₁₅(CCT)₄(CTT)₄(CCT)₁(CTT)₃N₁₈ 19 916 (CCT)₃(CTT)₅N₂₀[(CTT)₁(CTG)₁]₃(CT)₁ (CTT) ₁₈N₈(CTT)₄ (CCT)₃(CTT)₅N₂₀[(CTT)₁(CTG)₁]₃(CT)₁ (CTT) ₁₇N₈(CTT)₄ [(CTC)₁(CTT)₁]₃[(CTC)₁(TTT)₁]₁(CTT)₅ [(CTC)₁(CTT)₁]₃[(CTC)₁(TTT)₁](CTT)₅ DYS614 (CTT)₄(CCT)₁(CTT)₃N₁₅(CCT)₄(CTT)₄(CCT)₁(CTT)₃N₁₈ (CTT)₄(CCT)₁(CTT)₃N₁₅(CCT)₄(CTT)₄(CCT)₁(CTT)₃N₁₈ 45 1283 (CCT)₃(CTT)₅N₂₀[(CTT)₁(CTG)₁]₃(CT)₁ (CTT) ₁₈N₈(CTT)₄ (CCT)₃(CTT)₅N₂₀[(CTT)₁(CTG)₁]₃(CT)₁ (CTT) ₁₉N₈(CTT)₄ [(CTC)₁(CTT)₁]₃[(CTC)₁(TTT)₁]₁(CTT)₅ [(CTC)₁(CTT)₁]₃[(CTC)₁(TTT)₁]₁(CTT)₅ DYS614 (CTT)₄(CCT)₁(CTT)₃N₁₅(CCT)₄(CTT)₄(CCT)₁(CTT)₃N₁₈ (CTT)₄(CCT)₁(CTT)₃N₁₅(CCT)₄(CTT)₄(CCT)₁(CTT)₃N₁₈ 27 1583 (CCT)₃(CTT)₅N₂₀[(CTT)₁(CTG)₁]₃(CT)₁ (CTT) ₁₈N₈(CTT)₄ (CCT)₃(CTT)₅N₂₀[(CTT)₁(CTG)₁]₃(CT)₁ (CTT) ₁₉N₈(CTT)₄ [(CTC)₁(CTT)₁]₃[(CTC)₁(TTT)₁]₁(CTT)₅ [(CTC)₁(CTT)₁]₃[(CTC)₁(TTT)₁]₁(CTT)₅ DYS614 (CTT)₄(CCT)₁(CTT)₃N₁₅(CCT)₄(CTT)₄(CCT)₁(CTT)₃N₁₈ (CTT)₄(CCT)₁(CTT)₃N₁₅(CCT)₄(CTT)₄(CCT)₁(CTT)₃N₁₈ 19 1784 (CCT)₃(CTT)₅N₂₀[(CTT)₁(CTG)₁]₃(CT)₁ (CTT) ₁₉N₈(CTT)₄ (CCT)₃(CTT)₅N₂₀[(CTT)₁(CTG)₁]₃(CT)₁ (CTT) ₁₈N₈(CTT)₄ [(CTC)₁(CTT)₁]₃[(CTC)₁(TTT)₁]₁(CTT)₅ [(CTC)₁(CTT)₁]₃[(CTC)₁(TTT)₁]₁(CTT)₅ DYS614 (CTT)₄(CCT)₁(CTT)₃N₁₅(CCT)₄(CTT)₄(CCT)₁(CTT)₃N₁₈ (CTT)₄(CCT)₁(CTT)₃N₁₅(CCT)₄(CTT)₄(CCT)₁(CTT)₃N₁₈ 52 1965 (CCT)₃(CTT)₅N₂₀[(CTT)₁(CTG)₁]₃(CT)₁ (CTT) ₁₈N₈(CTT)₄ (CCT)₃(CTT)₅N₂₀[(CTT)₁(CTG)₁]₃(CT)₁ (CTT) ₁₆N₈(CTT)₄ [(CTC)₁(CTT)₁]₃[(CTC)₁(TTT)₁]₁(CTT)₅ [(CTC)₁(CTT)₁]₃[(CTC)₁(TTT)₁]₁(CTT)₅ DYS616 (TAT) ₁₄(CAT)₁(TAT)₃ (TAT) ₁₅(CAT)₁(TAT)₃ 25 40 DYS616 (TAT) ₁₅(CAT)₁(TAT)₃ (TAT) ₁₄(CAT)₁(TAT)₃ 41 417 DYS622 (GAAA)₆(AGAAG)₁ (GAAA) ₁₂ (GAAA)₆(AGAAG)₁ (GAAA) ₁₃ 33 187 DYS622 (GAAA)₆(AGAAG)₁ (GAAA) ₁₄ (GAAA)₆(AGAAG)₁ (GAAA) ₁₅ 34 308 DYS622 (GAAA)₆(AGAAG)₁ (GAAA) ₁₄ (GAAA)₆(AGAAG)₁ (GAAA) ₁₃ 30 842 DYS622 (GAAA)₆(AGAAG)₁ (GAAA) ₁₁ (GAAA)₆(AGAAG)₁ (GAAA) ₁₀ 19 1006 DYS622 (GAAA)₆(AGAAG)₁ (GAAA) ₁₃ (GAAA)₆(AGAAG)₁ (GAAA) ₁₂ 21 1436 DYS625 (CTTT)₄(TTCT)₁(CTTT)₃(TTT)₁(CTTT)₄(TT)₁(CTTT)₃N₄₇ (CTTT)₄(TTCT)₁(CTTT)₃(TTT)₁(CTTT)₄(TT)₁(CTTT)₃N₄₇ 38 445 (CTTT) ₄(CT)₁(CTTT)₄(CCTT)₁(CTTT)₃N₁₀(CTTT)₃ (CTTT) ₃(CT)₁(CTTT)₄(CCTT)₁(CTTT)₃N₁₀(CTTT)₃ DYS626 (GAAA) ₁₉N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ (GAAA) ₂₀N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ 42 383 (GAAA)₂(GAAG)₁(GAAA)₃ (GAAA)₂(GAAG)₁(GAAA)₃ DYS626 (GAAA) ₁₆N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ (GAAA) ₁₇N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ 37 388 (GAAA)₂(GAAG)₁(GAAA)₃ (GAAA)₂(GAAG)₁(GAAA)₃ DYS626 (GAAA) ₁₇N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ (GAAA) ₁₈N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ 35 500 (GAAA)₂(GAAG)₁(GAAA)₃ (GAAA)₂(GAAG)₁(GAAA)₃ DYS626 (GAAA) ₁₈N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ (GAAA) ₁₇N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ 38 529 (GAAA)₂(GAAG)₁(GAAA)₃ (GAAA)₂(GAAG)₁(GAAA)₃ DYS626 (GAAA) ₁₉N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ (GAAA) ₁₈N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ 24 571 (GAAA)₂(GAAG)₁(GAAA)₃ (GAAA)₂(GAAG)₁(GAAA)₃ DYS626 (GAAA) ₁₈N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ (GAAA) ₁₉N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ 40 612 (GAAA)₂(GAAG)₁(GAAA)₃ (GAAA)₂(GAAG)₁(GAAA)₃ DYS626 (GAAA) ₁₇N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ (GAAA) ₁₈N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ 29 650 (GAAA)₂(GAAG)₁(GAAA)₃ (GAAA)₂(GAAG)₁(GAAA)₃ DYS626 (GAAA) ₁₉N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ (GAAA) ₂₀N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ 36 733 (GAAA)₂(GAAG)₁(GAAA)₃ (GAAA)₂(GAAG)₁(GAAA)₃ DYS626 (GAAA) ₁₈N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ (GAAA) ₁₉N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ 41 779 (GAAA)₂(GAAG)₁(GAAA)₃ (GAAA)₂(GAAG)₁(GAAA)₃ DYS626 (GAAA) ₂₀N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ (GAAA) ₁₉N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ 29 901 (GAAA)₂(GAAG)₁(GAAA)₃ (GAAA)₂(GAAG)₁(GAAA)₃ DYS626 (GAAA) ₂₀N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ (GAAA) ₂₁N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ 27 953 (GAAA)₂(GAAG)₁(GAAA)₃ (GAAA)₂(GAAG)₁(GAAA)₃ DYS626 (GAAA) ₁₉N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ (GAAA) ₂₀N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ 39 1071 (GAAA)₂(GAAG)₁(GAAA)₃ (GAAA)₂(GAAG)₁(GAAA)₃ DYS626 (GAAA) ₁₇N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ (GAAA) ₁₈N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ 17 1109 (GAAA)₂(GAAG)₁(GAAA)₃ (GAAA)₂(GAAG)₁(GAAA)₃ DYS626 (GAAA) ₁₉N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ (GAAA) ₂₀N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ 33 1112 (GAAA)₂(GAAG)₁(GAAA)₃ (GAAA)₂(GAAG)₁(GAAA)₃ DYS626 (GAAA) ₁₉N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ (GAAA) ₂₀N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ 27 1389 (GAAA)₂(GAAG)₁(GAAA)₃ (GAAA)₂(GAAG)₁(GAAA)₃ DYS626 (GAAA) ₁₉N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ (GAAA) ₁₈N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ 25 1445 (GAAA)₂(GAAG)₁(GAAA)₃ (GAAA)₂(GAAG)₁(GAAA)₃ DYS626 (GAAA) ₁₆N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ (GAAA) ₁₅N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ 25 1514 (GAAA)₂(GAAG)₁(GAAA)₃ (GAAA)₂(GAAG)₁(GAAA)₃ DYS626 (GAAA) ₁₈N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ (GAAA) ₁₉N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ 19 1530 (GAAA)₂(GAAG)₁(GAAA)₃ (GAAA)₂(GAAG)₁(GAAA)₃ DYS626 (GAAA) ₁₉N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ (GAAA) ₂₀N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ 59 1823 (GAAA)₂(GAAG)₁(GAAA)₃ (GAAA)₂(GAAG)₁(GAAA)₃ DYS626 (GAAA) ₂₂N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ (GAAA) ₂₁N₂₄(GAAA)₃N₆(GAAA)₅(AAA)₁ 56 1907 (GAAA)₂(GAAG)₁(GAAA)₃ (GAAA)₂(GAAG)₁(GAAA)₃ DYS627 (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₂₁N₈₁(AAGG)₃ (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₂₀N₈₁(AAGG)₃ 25 4 DYS627 (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₂₂N₈₁(AAGG)₃ (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₂₁N₈₁(AAGG)₃ 36 49 DYS627 (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₁₈N₈₁(AAGG)₃ (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₁₉N₈₁(AAGG)₃ 29 82 DYS627 (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₁₈N₈₁(AAGG)₃ (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₁₉N₈₁(AAGG)₃ 39 112 DYS627 (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₁₉N₈₁(AAGG)₃ (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₁₈N₈₁(AAGG)₃ 27 170 DYS627 (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₂₀N₈₁(AAGG)₃ (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₂₁N₈₁(AAGG)₃ 34 243 DYS627 (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₁₉N₈₁(AAGG)₃ (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₁₈N₈₁(AAGG)₃ 20 256 DYS627 (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₁₉N₈₁(AAGG)₃ (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₂₀N₈₁(AAGG)₃ 21 328 DYS627 (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₁₉N₈₁(AAGG)₃ (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₂₀N₈₁(AAGG)₃ 31 331 DYS627 (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₁₈N₈₁(AAGG)₃ (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₁₇N₈₁(AAGG)₃ 37 355 DYS627 (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₂₀N₈₁(AAGG)₃ (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₂₁N₈₁(AAGG)₃ 23 496 DYS627 (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₂₃N₈₁(AAGG)₃ (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₂₂N₈₁(AAGG)₃ 35 500 DYS627 (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₂₀N₈₁(AAGG)₃ (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₁₉N₈₁(AAGG)₃ 36 619 DYS627 (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₂₀N₈₁(AAGG)₃ (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₁₉N₈₁(AAGG)₃ 25 711 DYS627 (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₁₉N₈₁(AAGG)₃ (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₁₈N₈₁(AAGG)₃ 20 742 DYS627 (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₁₉N₈₁(AAGG)₃ (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₂₀N₈₁(AAGG)₃ 29 789 DYS627 (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₁₉N₈₁(AAGG)₃ (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₂₀N₈₁(AAGG)₃ Unknown 1310 DYS627 (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₁₅N₈₁(AAGG)₃ (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₁₆N₈₁(AAGG)₃ 22 1323 DYS627 (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₁₈N₈₁(AAGG)₃ (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₁₉N₈₁(AAGG)₃ 42 1407 DYS627 (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₂₂N₈₁(AAGG)₃ (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₂₃N₈₁(AAGG)₃ 17 1416 DYS627 (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₁₉N₈₁(AAGG)₃ (AGAA)₃N₁₆(AGAG)₃ (AAAG) ₂₀N₈₁(AAGG)₃ 54 1860 DYS629 (TATC) ₉ (TATC) ₁₀ 29 609 DYS630 (AAAG)₄(AGAG)₃N₁₈ (AAAG) ₁₄ (AAAG)₄(AGAG)₃N₁₈ (AAAG) ₁₅ 21 46 DYS630 (AAAG)₄(AGAG)₃N₁₈ (AAAG) ₁₅ (AAAG)₄(AGAG)₃N₁₈ (AAAG) ₁₄ 33 53 DYS630 (AAAG)₄(AGAG)₃N₁₈ (AAAG) ₁₈ (AAAG)₄(AGAG)₃N₁₈ (AAAG) ₁₇ 23 96 DYS630 (AAAG)₄(AGAG)₃N₁₈ (AAAG) ₁₆ (AAAG)₄(AGAG)₃N₁₈ (AAAG) ₁₅ 40 255 DYS630 (AAAG)₄(AGAG)₃N₁₈ (AAAG) ₁₅ (AAAG)₄(AGAG)₃N₁₈ (AAAG) ₁₆ 30 448 DYS630 (AAAG)₄(AGAG)₃N₁₈ (AAAG) ₁₃ (AAAG)₄(AGAG)₃N₁₈ (AAAG) ₁₄ 21 478 DYS630 (AAAG)₄(AGAG)₃N₁₈ (AAAG) ₁₇ (AAAG)₄(AGAG)₃N₁₈ (AAAG) ₁₈ 39 501 DYS630 (AAAG)₄(AGAG)₃N₁₈ (AAAG) ₁₄ (AAAG)₄(AGAG)₃N₁₈ (AAAG) ₁₅ 36 665 DYS631 (AATA)₄(CATA)₁ (AATA) ₁₁ (AATA)₄(CATA)₁ (AATA) ₁₀ 47 347 DYS635 (TCTA)₄(TGTA)₂(TCTA)₂(TGTA)₂(TCTA)₂ (TCTA) ₁₂ (TCTA)₄(TGTA)₂(TCTA)₂(TGTA)₂(TCTA)₂ (TCTA) ₁₁ 53 35 DYS635 (TCTA)₄(TGTA)₂(TCTA)₂(TGTA)₂(TCTA)₂ (TCTA) _(13,14) (TCTA)₄(TGTA)₂(TCTA)₂(TGTA)₂(TCTA)₂ (TCTA) ₁₃ 33 528 DYS635 (TCTA)₄(TGTA)₂(TCTA)₂(TGTA)₂(TCTA)₂ (TCTA) ₁₃ (TCTA)₄(TGTA)₂(TCTA)₂(TGTA)₂(TCTA)₂ (TCTA) ₁₂ 36 617 DYS635 (TCTA)₄(TGTA)₂(TCTA)₂(TGTA)₂(TCTA)₂ (TCTA) ₁₂ (TCTA)₄(TGTA)₂(TCTA)₂(TGTA)₂(TCTA)₂ (TCTA) ₁₁ 26 800 DYS635 (TCTA)₄(TGTA)₂(TCTA)₂(TGTA)₂(TCTA)₂ (TCTA) ₁₂ (TCTA)₄(TGTA)₂(TCTA)₂(TGTA)₂(TCTA)₂ (TCTA) ₁₁ 29 1674 DYS635 (TCTA)₄(TGTA)₂(TCTA)₂(TGTA)₂(TCTA)₂ (TCTA) ₁₁ (TCTA)₄(TGTA)₂(TCTA)₂(TGTA)₂(TCTA)₂ (TCTA) ₁₂ 52 1891 DYS637 (AAAT)₄ (ACAT) ₁₁ (AAAT)₄ (ACAT) ₁₀ 25 950 DYS638 (TTTA) ₁₁ (TTTA) ₁₂ 56 1677 DYS643 (AAAT) ₁₁ (AAAT) ₁₂ 32 95 DYS643 (AAAT) ₁₃ (AAAT) ₁₄ 19 1697 DYS644 (TTTTA)₁₀ (TTTTA) ₇ (TTTTA)₁₀ (TTTTA) ₈ 22 487 DYS644 (TTTTA)₁₀ (TTTTA) ₆ (TTTTA)₁₀ (TTTTA) ₅ 24 681 DYS644 (TTTTA) ₁₀(TTTA)₁(TTTTA)₁₃ (TTTTA) ₁₁(TTTA)₁(TTTTA)₁₃ 21 1667 DYS644 (TTTTA)₁₀ (TTTTA) ₆ (TTTTA)₁₀ (TTTTA) ₇ 19 1717 DYS644 (TTTTA)₁₀ (TTTTA) ₇ (TTTTA)₁₀ (TTTTA) ₆ 50 1832 Y-GATA-A10 (ATCT) ₁₃ (ATCT) ₁₄ 41 417 Y-GATA-A10 (ATCT) ₁₄ (ATCT) ₁₅ 35 735 Y-GATA-A10 (ATCT) ₁₃ (ATCT) ₁₂ 24 855 Y-GATA-A10 (ATCT) ₁₃ (ATCT) ₁₂ 46 1252 Y-GATA-A10 (ATCT) ₁₃ (ATCT) ₁₄ 40 1606 Y-GATA-H4 (TAGA)₃N₁₂(TAGG)₃ (TAGA) ₁₂N₂₂(TAGA)₄ (TAGA)₃N₁₂(TAGG)₃ (TAGA) ₁₁N₂₂(TAGA)₄ 23 251 Y-GATA-H4 (TAGA)₃N₁₂(TAGG)₃ (TAGA) ₁₁N₂₂(TAGA)₄ (TAGA)₃N₁₂(TAGG)₃ (TAGA) ₁₂N₂₂(TAGA)₄ 19 1004 Y-GATA-H4 (TAGA)₃N₁₂(TAGG)₃ (TAGA) ₁₂N₂₂(TAGA)₄ (TAGA)₃N₁₂(TAGG)₃ (TAGA) ₁₁N₂₂(TAGA)₄ 29 1051 Y-GATA-H4 (TAGA)₃N₁₂(TAGG)₃ (TAGA) ₁₃N₂₂(TAGA)₄ (TAGA)₃N₁₂(TAGG)₃ (TAGA) ₁₂N₂₂(TAGA)₄ 42 1411 Y-GATA-H4 (TAGA)₃N₁₂(TAGG)₃ (TAGA) ₁₃N₂₂(TAGA)₄ (TAGA)₃N₁₂(TAGG)₃ (TAGA) ₁₂N₂₂(TAGA)₄ 53 1799

Data 3. Ability of 13 rapidly-mutating RM Y-STRs and 17 YFiler Y-STRs to differentiate between male relatives by one or more mutations from analyzing 103 pairs from 80 male pedigrees, according to the number of generations separating members of the same pedigree. Number of RM Meioses RM Y-STR Y-STR Locus Yfiler Yfiler Locus Separating Pair Mutations Comparisons Mutations Comparisons 1 1 9 0 17 1 1 12 0 17 1 1 12 0 17 1 1 11 0 17 1 1 10 0 17 1 1 12 0 17 1 2 5 0 17 1 0 13 0 17 1 1 12 0 17 1 0 13 0 17 1 0 13 0 17 1 1 13 0 17 1 0 13 0 17 1 0 13 0 17 1 3 11 0 17 1 1 10 0 17 1 0 13 0 17 1 1 10 0 17 1 1 4 0 17 1 1 12 0 17 2 1 12 0 17 2 2 11 0 17 2 1 8 0 17 2 2 11 0 17 2 2 13 0 17 2 1 9 0 17 2 2 13 0 17 2 0 13 0 17 2 0 13 0 17 2 0 13 0 17 2 1 13 0 17 2 0 13 0 17 2 0 13 0 17 2 1 12 0 17 2 3 13 0 17 2 0 13 0 17 2 0 13 0 17 2 0 13 1 17 2 0 13 0 17 2 0 13 0 17 2 3 13 0 17 2 0 12 0 17 2 4 13 0 17 2 1 13 0 17 2 3 13 0 17 2 0 13 0 17 2 0 13 0 17 2 0 13 0 17 2 1 13 0 17 2 0 13 0 17 2 1 10 1 17 2 1 13 0 17 2 1 13 0 17 2 2 3 0 17 3 0 13 0 17 3 0 13 0 17 3 0 13 0 17 3 2 12 0 17 3 2 12 0 17 3 2 13 0 17 3 3 13 0 17 4 0 13 0 17 4 1 13 0 17 4 1 13 0 17 5 1 5 0 17 5 1 13 0 17 5 1 12 0 17 5 2 12 0 17 6 3 9 0 17 6 1 10 0 17 6 1 13 2 17 6 5 12 1 17 6 3 13 0 17 6 4 13 0 17 6 3 13 0 17 6 0 13 0 17 6 2 13 0 17 7 0 13 0 17 7 4 13 1 17 8 3 13 0 17 8 4 13 0 17 8 2 13 0 17 8 0 13 0 17 8 0 13 1 17 8 4 13 0 17 8 2 13 0 17 9 1 13 1 17 10  1 13 0 17 10  4 12 1 17 10  2 13 0 17 10  3 13 0 17 10  3 13 1 17 10  1 12 2 17 10  0 12 1 17 11  6 13 0 17 11  6 13 0 17 11  3 12 0 17 11  4 13 2 17 11  1 13 1 17 11  3 13 0 17 13  4 12 1 17 13  5 13 0 17 20  4 13 0 17 Total 158 1246 17 1751 Average 1.53 12.10 0.17 17 

What is claimed is:
 1. A set of amplification primer pairs, comprising primers for the amplification of at least 2 Y-STR markers selected from the group consisting of DYF387S1, DYF399S1, DYF403S1, DYF404S1, DYS449, DYS518, DYS526, DYS547, DYS570, DYS576, DYS612, DYS626 and DYS627.
 2. A set of primers according to claim 1, wherein the primers can be used to co-amplify at least 3-13 loci from the group.
 3. A set of primer according to claim 1, wherein the primers can be used to amplify all loci from the group.
 4. A method of identifying an individual, the method comprising determining the allele of at least 2 Y-STR markers selected from the group consisting of DYF387S1, DYF399S1, DYF403S1, DYF404S1, DYS449, DYS518, DYS526, DYS547, DYS570, DYS576, DYS612, DYS626 and DYS627.
 5. The method of claim 4, wherein the allele is identified by PCR.
 6. The method of claim 5, wherein the PCR is multiplex PCR that co-amplifies the at least 3 of the markers.
 7. The method of claim 5, wherein the PCR uses primers that are labeled with a fluorescent dye.
 8. The method of claim 4, wherein the allele is identified by mass spectroscopy, capillary electrophoresis, or gel electrophoresis.
 9. The method of claim 4, wherein the PCR co-amplifies at least one the loci and an autosomal STR.
 10. The method of claim 9, wherein the autosomal STR is selected from the group consisting of D3S1358, vWA, FGA, D8S1179, D21S11, D18S51, D5S818, D13S317, D7S820, D16S539, THO1, TPDX, and CSF1 PO.
 11. A kit for identifying the allele of at least 2 Y chromosome SIRS markers, wherein the markers are selected from the group consisting of DYF387S1, DYF399S1, DYF403S1, DYF404S1, DYS449, DYS518, DYS526, DYS547, DYS570, DYS576, DYS612, DYS626 and DYS627, the kit comprising primers for the amplification of at least 3 loci, and an allelic ladder representative of the selected markers.
 12. An allelic ladder size standard for calling one or more alleles of an STR from at least 2 of the Y-STR markers selected from the group consisting of DYF387S1, DYF399S1, DYF403S1, DYF404S1, DYS449, DYS518, DYS526, DYS547, DYS570, DYS576, DYS612, DYS626 and DYS627.
 13. A set of amplification primer pairs, comprising at least one primer pair selected from the group consisting of DYF387S1, DYF399S1, DYF403S1, DYF404S1, DYS449, DYS518, DYS526, DYS547, DYS570, DYS576, DYS612, DYS626 and DYS627.
 14. A set of amplification primer pairs of the identification of a male, comprising primers for the Y-STR markers consisting of DYF387S1, DYF399S1, DYF403S1, DYF404S1, DYS449, DYS518, DYS526, DYS547, DYS570, DYS576, DYS612, DYS626 and DYS627. 